A new strategy of discrimination of a point mutation by tandem of short oligonucleotides

A new strategy based on the use of cooperative tandems of short oligonucleotide 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.     

Mini-antisense Oligonucleotides

Abstract

A new strategy of selective DNA target modification was proposed. The using of reactive derivatives of short oligonucleotides in the presence of flanking effector pair allows one to modify DNA target only when the perfect complementary complex of DNA target and oligonucleotide tandem is formed.     

Special Properties of Modification of SsDNA Target by Alkylating Derivatives of Oligonucleotides in Tandem Complexes

Abstract

The influence of an effector (di-N-(2-hydroxyethyl)-phenazinium derivative of oligonucleotide) on modification of the DNA target by alkylating derivatives of oligonucleotides having various hybridization properties was studied. Being adjacent to the alkylating group of the reagent, the effector enhances the target modification if the oligonucleotide reagent has low hybridization properties and suppresses the modification if the reagent can form the stable complex with the DNA target at the used conditions.

     

Comparison of Complex DNA Mixtures with Generic Oligonucleotide Microchips

Abstract

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 VD-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.     

Sequencing by hybridization with the generic 6-mer oligonucleotide microarray: an advanced scheme for data processing

DNA sequencing by hybridization was carried out with a microarray of all 4(6) = 4,096 hexadeoxyribonucleotides (the generic microchip). The oligonucleotides immobilized in 100 x 100 x 20-microm polyacrylamide gel pads of the generic microchip were hybridized with fluorescently labeled ssDNA, providing perfect and mismatched duplexes. Melting curves were measured in parallel for all microchip duplexes with a fluorescence microscope equipped with CCD camera. This allowed us to discriminate the perfect duplexes formed by the oligonucleotides, which are complementary to the target DNA. The DNA sequence was reconstructed by overlapping the complementary oligonucleotide probes. We developed a data processing scheme to heighten the discrimination of perfect duplexes from mismatched ones. The procedure was united with a reconstruction of the DNA sequence. The scheme includes the proper definition of a discriminant signal, preprocessing, and the variational principle for the sequence indicator function. The effectiveness of the procedure was confirmed by sequencing, proofreading, and nucleotide polymorphism (mutation) analysis of 13 DNA fragments from 31 to 70 nucleotides long.     

Properties of the 3' to 5' exonuclease associated with calf DNA polymerase delta

The 3' to 5' exonuclease of calf thymus DNA polymerase delta has properties expected of a proofreading nuclease. It digests either single-stranded DNA or the single-stranded nucleotides of a mismatched primer on a DNA template by a nonprocessive mechanism. The distribution of oligonucleotide products suggests that a significant portion of the enzyme dissociates after the removal of one nucleotide. This mechanism is expected if the substrate in vivo is an incorrect nucleotide added by the polymerase. Digestion of single-stranded DNA does not proceed to completion, producing final products six to seven nucleotides long. Digestion of a long mismatched terminus accelerates when the mismatched region is reduced to less than six nucleotides. At the point of complementation, the digestion rate is greatly reduced. These results suggest that short mismatched regions are a preferred substrate. The use of a mismatched primer-template analogue, lacking the template single strand, greatly lowers digestion efficiency at the single-stranded 3'-terminus, suggesting that the template strand is important for substrate recognition. When oligonucleotides were examined for effectiveness as exonuclease inhibitors, (dG)8 was found to be the most potent inhibitor of single-stranded DNA digestion. (dG)8 was less effective at inhibiting digestion of mismatched primer termini, again suggesting that this DNA is a preferred substrate. Overall, these results indicate that the exonuclease of DNA polymerase delta efficiently removes short mismatched DNA, a structure formed from misincorporation during DNA synthesis.     

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.     

Cooperative Interactions in Photosensitized Modification of DNA with Oligonucleotide-derived Binary Reagents

Quantitative characteristics of thermodynamic and kinetic cooperativity arising in the process of photomodification of a single-stranded DNA fragment with binary systems of oligonucleotide conjugates forming an active site on the target were studied. Oligonucleotides of the binary system were complementary to adjacent segments of the DNA target, and contained arylazide (X) and perylene (S) residues covalently attached to their terminal phosphates. Upon irradiation at the perylene absorption wavelength, the target was modified by the arylazide residue, which was activated owing to the contiguity with the sensitizing perylene group in the tandem complex. Basing on the kinetic data, the constants of association of both derivatives of oligonucleotides with the target were determined: K _x = 1.13 · 10⁶ M^–1, K _s = 1.49 · 10⁴ M^–1. It was determined that association of both oligonucleotides with the target proceeded with a positive cooperativity characterized by parameter = 45. The kinetic cooperativity parameter was found to be approximately equal to 200; this characterized the acceleration of target modification in complex with the binary reagent versus that in the absence of sensitizer.     

Chemical and Photochemical Ligation of Oligonucleotide Blocks

Abstract

Several efficient means for joining oligonucleotides in dilute solution by non-natural internucleotide bridges are discussed. It is also shown that an oligonucleotide containing a -OP(O)(O^?)S- link can hnction as an effective template in PCR amplification and that oligonucleotide probes containing stilbenedicarboxamide groups can serve in monitoring the presence of mismatched bases in an oligonucleotide target.     

Interactions of derivatives of short oligonucleotides with nucleic acids. VII. Effect of conformation changes in the duplex structure on on the specificity and efficacy of modification of target DNA by alkylating oligonucleotide derivatives]

The modification of a target DNA by alkylating oligonucleotide derivatives possessing various capacities for complex formation was studied. The binding properties of oligonucleotides were changed either by increasing their length (tetra-, octa-, and dodecamers) or by introducing a point substitution and/or an N-(2-hydroxyethylphenazinium) residue. It was found that conformational changes occurring in the structure of the target.reagent complex upon elevating the reaction temperature affect the efficiency and site-specificity of the alkylation. In the case of complete saturation of the target with the reagent, an increase in the hybridization ability of the reagent reduced the efficiency of the target modification. It was found that the modification by the tetranucleotide reagent (in the presence of an effector adjacent to the 3' end) occurs exclusively at an intracomplex target base. In the case of the dodecamer, which forms a stable, highly cooperative complex with the target, several bases of the target undergo alkylation, and an increase in temperature changes the site-specificity of alkylation. In this process, the redistribution of the target modification sites toward stronger nucleophilic centers enhances alkylation at temperatures near the melting temperature of the target.dodecanucleotide complex despite a decrease in the extent of target association.     

Linear Polyethylenimine as a Tool for Comparative Studies of Antisense and Short Double-Stranded RNA Oligonucleotides

Abstract

Despite the recently enlarged field of available RNA knock-down technologies, e.g., antisense oligonucleotides (ASOs) and duplexes of synthetic 21 nucleotides RNAs (siRNAs), no versatile transfection reagent has been reported to deliver different nucleic acids formats at high rates of efficiency. We have evaluated the versatility and efficacy of linear PEI in transfecting and properly delivering a broad panel of nucleic acids such as short oligonucleotides and double-stranded RNA into cells in culture.     

Complementary addressed modification and cleavage of a single stranded DNA fragment with alkylating oligonucleotide derivatives.

A single stranded DNA fragment was modified with alkylating derivatives of oligonucleotides complementary to a certain nucleotide sequences in the fragment. The derivatives carried aromatic 2-chloroethylamino groups at their 3'- or 5'-terminal nucleotide residues. Some of the derivatives carried both alkylating group and intercalating phenazine group which stabilized complementary complexes. It was found that these oligonucleotide derivatives modify the DNA fragment in a specific way near the target complementary nucleotide sequences, and the DNA fragment can be cleaved at the alkylated nucleotides positions. Alkylating derivatives carrying phenazine groups were found to be the most efficient in reaction with the DNA fragment.     

The Accurate Detection of One Point Mutations by Ligation of Short Oligonucleotides

Abstract

A new approach which is based on the selective ligation of the cooperative tandem of three short oligonucleotides (octa-, tetra- and octamers) is proposed to reveal a point mutation in DNA. The ligation product is registered only when the correct complex of the tandem and DNA is formed. If there is one substitution base in the binding site of tetranucleotide in DNA, no product of ligation is observed.

     

Sensitive and specific detection of microRNAs by northern blot analysis using LNA-modified oligonucleotide probes

We describe here a new method for highly efficient detection of microRNAs by northern blot analysis using LNA (locked nucleic acid)-modified oligonucleotides. In order to exploit the improved hybridization properties of LNA with their target RNA molecules, we designed several LNA-modified oligonucleotide probes for detection of different microRNAs in animals and plants. By modifying DNA oligonucleotides with LNAs using a design, in which every third nucleotide position was substituted by LNA, we could use the probes in northern blot analysis employing standard end-labelling techniques and hybridization conditions. The sensitivity in detecting mature microRNAs by northern blots was increased by at least 10-fold compared to DNA probes, while simultaneously being highly specific, as demonstrated by the use of different single and double mismatched LNA probes. Besides being highly efficient as northern probes, the same LNA-modified oligonucleotide probes would also be useful for miRNA in situ hybridization and miRNA expression profiling by LNA oligonucleotide microarrays.     

The Synthesis of Branched Oligonucleotides as Signal Amplification Multimers for Use in Nucleic Acid Assays

Abstract

Branched oligonucleotides have been synthesized using phosphoramidite derivatives with two protected hydroxyl functions. These molecules are employed for a label amplification strategy used in DNA probe diagnostics.     

Parallel thermodynamic analysis of duplexes on oligodeoxyribonucleotide microchips.

A microchip method has been developed for massive and parallel thermodynamic analyses of DNA duplexes. Fluorescently labeled oligonucleotides were hybridized with oligonucleotides immobilized in the 100 x 100 x 20 mum gel pads of the microchips. The equilibrium melting curves for all microchip duplexes were measured in real time in parallel for all microchip duplexes. Thermodynamic data for perfect and mismatched duplexes that were obtained using the microchip method directly correlated with data obtained in solution. Fluorescent labels or longer linkers between the gel and the oligonucleotides appeared to have no significant effect on duplex stability. Extending the immobilized oligonucleotides with a four-base mixture from the 3'-end or one or two universal bases (5-nitroindole) from the 3'- and/or 5'-end increased the stabilities of their duplexes. These extensions were applied to increase the stabilities of the duplexes formed with short oligonucleotides in microchips, to significantly lessen the differences in melting curves of the AT- and GC-rich duplexes, and to improve discrimination of perfect duplexes from those containing poorly recognized terminal mismatches. This study explored a way to increase the efficiency of sequencing by hybridization on oligonucleotide microchips.     

DNA base mismatch detection with bulky rhodium intercalators: synthesis and applications

This protocol describes the syntheses and applications of two metallointercalators, Rh(bpy)2(chrysi)3+ and Rh(bpy)2(phzi)3+, that target single base mismatches in DNA. The complexes bind mismatched DNA sites specifically and, upon photoactivation, promote strand scission neighboring the mismatch. Owing to their high specificity and sequence context independence, targeting mismatches with these complexes offers an attractive alternative to current mismatch- and SNP-detection methodologies. This protocol also describes the synthesis of these complexes and their use in marking mismatched sites. Irradiation of 32P-labeled duplex DNA with either intercalator followed by denaturing PAGE allows the detection of mismatches in oligonucleotides. The protocol also outlines a method for efficient detection of single nucleotide polymorphisms (SNPs) in larger genes or plasmids. Pooled genes are denatured and re-annealed to form heteroduplexes; they are then incubated with either complex, irradiated and analyzed using capillary electrophoresis to probe for mismatches (SNP sites). The synthesis of the metallointercalators requires approximately 5-7 d. The mismatch- and SNP-detection experiments each require approximately 3 d.     

Complementary addressed modification of plasmid DNA

The possibility to accomplish the sequence-specific chemical modification of superhelical DNA with reactive oligonucleotide derivatives was demonstrated. Plasmids containing fragments of the immunoglobulin gene were modified with alkylating derivatives of oligonucleotides complementary to a nucleotide sequence in the immunoglobulin gene. In contrast to the relaxed plasmid DNAs, superhelical DNAs (sigma = -0.1) were found to be attacked by the derivatives at the target nucleotide sequence. The efficiency of the reaction increases with the increase of the plasmids negative superhelicity. It was found also that the denatured derivatives. The sequence-specific modification of plasmid DNAs with the reactive oligonucleotide derivatives can be used for the site-directed mutagenesis and the investigation of the repair processes.     

Recursive construction of perfect DNA molecules from imperfect oligonucleotides

Making faultless complex objects from potentially faulty building blocks is a fundamental challenge in computer engineering, nanotechnology and synthetic biology. Here, we show for the first time how recursion can be used to address this challenge and demonstrate a recursive procedure that constructs error‐free DNA molecules and their libraries from error‐prone oligonucleotides. Divide and Conquer (D&C), the quintessential recursive problem‐solving technique, is applied in silico to divide the target DNA sequence into overlapping oligonucleotides short enough to be synthesized directly, albeit with errors; error‐prone oligonucleotides are recursively combined in vitro, forming error‐prone DNA molecules; error‐free fragments of these molecules are then identified, extracted and used as new, typically longer and more accurate, inputs to another iteration of the recursive construction procedure; the entire process repeats until an error‐free target molecule is formed. Our recursive construction procedure surpasses existing methods for de novo DNA synthesis in speed, precision, amenability to automation, ease of combining synthetic and natural DNA fragments, and ability to construct designer DNA libraries. It thus provides a novel and robust foundation for the design and construction of synthetic biological molecules and organisms.