Specific oligonucleotide invasion into the end of DNA duplex

Phenomenon of the interaction of a double-stranded DNA fragment with an oligonucleotide complementary to the end of the duplex strand was demonstrated to occur via formation of three-stranded DNA structure with an oligonucleotide invasion. It was shown that oligonucleotides complementary to the duplex ends inhibit Holliday junction formation in solutions of homologous linear DNA fragments. This effect depends on the oligonucleotide concentration, sequence and their complementarity to the duplex ends. Formation of three-stranded complexes was demonstrated using radiolabeled oligonucleotides by agarose gel-electrophoresis followed by autoradiography. Analysis of three-stranded DNA structures by chemical cleavage of non-canonical base pairs revealed that oligonucleotide invades into duplex ends via a sequential displacement mechanism and that the level of the invasion may vary considerably.     

Kinetic trapping of H-DNA by oligonucleotide binding.

Homopurine-homopyrimidine mirror repeats are known to adopt the H form under acidic pH and/or negative supercoiling. In H-DNA, one half of the purine strand enters the triplex whereas the second half is unstructured and can form duplex with complementary oligonucleotide. However, because the same oligonucleotide can form triplex with the homopurine-homopyrimidine insert, one could expect that oligonucleotide would make H-DNA thermodynamically less favorable, as was claimed by Lyamichev et al. Nucl. Acids Res. 16, 2165-2178 (1988). Now we show that complex between oligonucleotide and H-DNA, formed under conditions favorable for the H-form extrusion, is kinetically trapped in superhelical DNA and remains stable up much higher pH values than H-DNA alone. Experiments on chemical probing show that such complex exists for a plasmid with native superhelical density at pH7. We have also used this approach to demonstrate a pH-dependent structural transition in yeast telomeric sequence, d(CACACCCA)16.     

Sequence-independent and linear variation of oligonucleotide DNA binding stabilities.

The ability to equalize the DNA binding stability of comprehensive sets of oligonucleotides is imperative for the application of sequencing by hybridization technology. By substitution of ribonucleotides into an oligonucleotide composed of deoxyribonucleotides, and vice versa, the duplex stability of the oligonucleotide is changed linearly with the number of serial alternations of sugar configurations within the molecule. Since this effort occurs independently of the actual base sequence, any set of oligonucleotides could be adjusted to a defined level of binding stability.     

Specific oligonucleotide invasion into an end of a DNA duplex

A new phenomenon was described: a double-stranded DNA fragment interacted with a single-stranded oligonucleotide complementary to the terminal region of one strand of the duplex to yield a complex with oligonucleotide invasion. Generation of Holliday junctions by homologous linear DNA fragments was less efficient in the presence of single-stranded oligonucleotides complementary to duplex ends. The effect depended on the oligonucleotide concentration, size, and complementarity to a duplex strand. Sequence-specific complexes with single strand invasion were detected in mixtures containing radiolabeled oligonucleotides and duplexes. A single-stranded oligonucleotide invaded a duplex even when its concentration was far lower than the duplex concentration. Complexes with single strand invasion were analyzed by chemical cleavage of noncanonical base pairs. Analysis showed that an oligonucleotide interacts with the complementary region of one strand of the duplex, gradually displacing the other strand. The extent of oligonucleotide invasion into the duplex considerably varied. Oligonucleotide invasion into duplexes became more efficient with increasing oligonucleotide size.     

A study of oligonucleotide reassociation using large arrays of oligonucleotides synthesised on a glass support.

An extensive analysis of oligonucleotide interactions was carried out by hybridising a synthetic pool of 256 10mers, A(C,T)8A, representing all oligopyrimidine octamer sequences to an array of four copies of all 256 different octapurine sequences. The resulting 256 duplexes were quantified by phosphorimaging and analysed to determine the dependence of duplex formation on base composition, sequence, and salt concentration. The results show that the base composition dependence of duplex formation can be reduced by high concentrations of tetramethylammonium chloride. This chaotropic solvent also increases duplex yield by up to fifty-fold.     

The kinetics of oligonucleotide replacements

The formation of a duplex between two nucleic acid strands is restricted if one of the strands forms an intra- or intermolecular secondary structure. The formation of the new duplex requires the dissociation and replacement of the initial structure. To understand the mechanism of this type of kinetics we studied the replacement of a labeled DNA oligonucleotide probe bound to a complementary DNA target with an unlabeled probe of the same sequence. The replacement kinetics were measured using a gel-shift assay for 12, 14 and 16-nucleotide probes as a function of temperature and concentration of the unlabeled probe. The results demonstrate that the overall replacement rate is a combination of two kinetic pathways: dissociative and sequential displacement. The dissociative pathway occurs by the spontaneous dissociation of the initial duplex followed by association of the target and unlabeled probe. The sequential displacement pathway requires only the partial melting of the initial duplex to allow for the formation of a branched nucleation complex with the unlabeled probe, followed by the complete displacement of the labeled probe by migration of the branch point. The contribution from the dissociative pathway is predominant at temperatures close to the melting point of the labeled probe, whereas the contribution from the displacement pathway prevails at lower temperatures and when the concentration of the replacing unlabeled probe is high. The results show that at physiological conditions, duplex formation between a single-stranded oligonucleotide probe and a structured region of a target molecule occurs mainly by the sequential-displacement mechanism.     

Efficient conjugation and characterization of distamycin-based peptides with selected oligonucleotide stretches

Selected sequences of oligodeoxyribonucleotides (ODNs) have been conjugated efficiently with distamycin-based peptides containing reactive cysteine and oxyamine functionalities at the C-terminus. The conjugation was performed easily within 30-60 min, using individual modified oligonucleotide stretches having sequences of 5'-d(GCTTTTTTCG)-3', 5'-d(GCTATATACG)-3', and 5'-AGCGCGCGCA-3'. Two types of linkages were used for making the covalent connection: (i) a five-membered thiazolidine ring and (ii) an oxime. These distamycin-like polyamide-ODN conjugates were then converted to the corresponding DNA duplexes using complementary oligonucleotide sequences. To elucidate the binding specificity of the distamycin-oligonucleotide conjugates, UV-melting temperature measurements were performed. These studies indicated that the distamycin-ODN conjugate favored binding with the duplex with sequence 5'-d(GCTTTTTTCG)-3' rather than 5'-d(GCTATATACG)-3'. On the other hand, no stabilization of the duplex with sequence 5'-d(AGCGCGCGCA)-3' was observed. UV results also suggest that the thiazolidine and oxime linkages do not significantly influence the process of distamycin binding to the minor groove surface of the DNA duplex. The results obtained from duplex UV-melting studies were further corroborated by a temperature-dependent study of the circular dichroism spectra of the conjugates and a fluorescence displacement titration assay using Hoechst 33258 fluorophore as a competitive binder for the minor groove. All these studies reinforce the fact that the specific stabilization of A/T rich DNA-DNA duplexes by distamycin was preserved upon conjugation with oligonucleotide stretches.     

Synthesis of oligonucleotide derivatives containing a bis-pyrene residue in the main chain.

The oligonucleotide having the bis-pyrene residue in the main chain was synthesized. The preparation of the bis-pyrene was started from the conversion of 2,2-bis-(bromomethyl)-1,3-propanediol into the protected bis-amino derivative. The reaction of the bis-amino derivative with 1-pyrenebutyric acid using DCC/HOBT afforded the desired bis-pyrene. This compound was then converted to the protected phosphormidite. The oligonucleotides possessing the bis-pyrene were synthesized by using the amidite. The oligonucleotides having the bis-pyrene residue can bind to DNA sequence in an aqueous solution to give the duplex with comparable thermal stability as that of the unmodified DNA/DNA duplex. The significantly enhanced pyrene-excimer fluorescence was observed upon hybridization of the bis-pyrene modified oligonucleotides with DNA.     

Immunochemical detection of multiple conformations within a 36 base pair oligonucleotide.

A 36 base pair chimeric oligonucleotide containing a central core of DNA duplex flanked by RNA/DNA hybrid at each end was synthesized. These distinct regions of the oligonucleotide adopt different conformations which were detected with antibody probes. Enzyme linked immunosorbent assays (ELISA) and a gel electrophoresis retardation assay were used to demonstrate the binding of antibodies which recognize B-DNA, Z-DNA and RNA/DNA hybrid. The DNA duplex core of this oligonucleotide adopts the B-conformation in 0.14 M NaCl. In high salt solution (4 M NaCl) the DNA core adopts the Z-conformation. The RNA/DNA hybrid at the ends of the oligomer adopt a conformation which is distinct from both B-DNA and A-RNA.     

End-filling of an oligonucleotide duplex containing an MDBP site in the human HSP70 promoter inhibits protein-DNA complex formation

A site from the promoter region of the human hsp70 gene binds with a high affinity to the ubiquitous mammalian protein called methylated DNA-binding protein (MDBP) when it is present in a CpG-methylated oligonucleotide duplex with only 14 base-pairs. Binding to this site is dependent upon CpG methylation. Surprisingly, when the same methylated sequence is present in a duplex that has 22 or more base-pairs, binding to this protein is greatly inhibited. Such a requirement for a short duplex region is seen only in certain of the cytosine methylation-dependent binding sites for this protein and is proposed to reflect differences in the conformation of the duplex due to small differences in the nucleotide sequence.     

Triple-helix formation is compatible with an adjacent DNA-protein complex.

The effect of oligonucleotide-directed triple-helix formation on the binding of a protein to an immediately adjacent sequence has been examined. A double-stranded oligonucleotide was designed with a target site for the binding of a pyrimidine oligonucleotide located immediately adjacent to the recognition sequence for the herpes simplex virus type 1 (HSV-1) origin of replication binding protein, which is encoded by the UL9 gene of HSV-1. Since the optimal conditions for the binding of the UL9 protein and the pyrimidine oligonucleotide to the duplex DNA are markedly different, a pyrimidine oligonucleotide was designed to optimize binding affinity and specificity for the target duplex oligonucleotide. Consideration was given to length and sequence composition in an effort to maximize triple-strand formation under conditions amenable to the formation of the UL9-DNA complex. Using gel mobility shift assays, a trimolecular complex composed of duplex DNA bound to both a third oligonucleotide strand and the UL9 protein was detected, indicating that the UL9-DNA complex is compatible with the presence of a triple helix in the immediately adjacent sequences.     

Radioprobing of DNA: distribution of DNA breaks produced by decay of 125I incorporated into a triplex-forming oligonucleotide correlates with geometry of the triplex.

The distribution of breaks produced in both strands of a DNA duplex by the decay of 125I carried by a triplex-forming DNA oligonucleotide was studied at single nucleotide resolution. The 125I atom was located in the C5 position of a single cytosine residue of an oligonucleotide designed to form a triple helix with the target sequence duplex. The majority of the breaks (90%) are located within 10 bp around the decay site. The addition of the free radical scavenger DMSO produces an insignificant effect on the yield and distribution of the breaks. These results suggest that the majority of these breaks are produced by the direct action of radiation and are not mediated by diffusible free radicals. The frequency of breaks in the purine strand was two times higher that in the pyrimidine strand. This asymmetry in the yield of breaks correlates with the geometry of this type of triplex; the C5 of the cytosine in the third strand is closer to the sugar-phosphate backbone of the purine strand. Moreover, study of molecular models shows that the yield of breaks at individual bases correlates with distance from the 125I decay site. We suggest the possible use of 125I decay as a probe for the structure of nucleic acids and nucleoprotein complexes.     

Design and simple routes of synthesis of oligonucleotide conjugates for studies of DNA triple helix formation

A series of oligonucleotides conjugated to intercalators, as well as fluorescent and lipophilic substances, minor groove binders and photoactive molecules were synthesized for studies of their ability to form a stable triple helix. Purine-rich short double stranded DNA fragments from HIV-1 genome and pyrimidine 16-mer oligodeoxyribonucleotide were used as models. A conjugate of a dipyrido[3,2-a:2',3'-c]phenazine-ruthenium (II) complex and a triple helix-forming oligonucleotide was constructed. Upon sequence-specific duplex and triplex formation of the conjugate, the ruthenium complex becomes highly fluorescent. The attached ruthenium complex induces a stabilization of the DNA triple helix and a significant increase of the time of residence of the third strand on the duplex.     

Solution structure of the parallel-stranded duplex oligonucleotide alpha-d(TCTAAAC)-beta-d(AGATTTG) via complete relaxation matrix analysis of the NOE effects and molecular mechanics calculations

The solution structure of the duplex formed by the association of the unnatural oligonucleotide alpha-d(TCTAAAC) with its natural and parallel complementary sequence beta-d(AGATTTG) was investigated by nuclear magnetic resonance spectroscopy and constrained molecular mechanics calculations. The structure was refined on the basis of interproton distances determined by NOE measurements for a series of mixing times. The NOE values were converted to distances by using the complete 134 x 134 relaxation matrix including all proton dipole-dipole interactions and spin diffusion. The computation of the relaxation matrix requires the Cartesian coordinates of the oligonucleotide, which are not known, a priori. To avoid this ambiguity, we used an iterative procedure in which the new distance constraints are obtained by using the complete relaxation matrix calculated from the previous structure. After three iterations, the process converged. The unnatural duplex alpha-d(TCTAAAC)-beta-d(AGATTTG) adopts in solution a right-helical structure with Watson-Crick base pairing, an anti conformation on the glycosyl linkage on the beta-strand, a syn conformation on the alpha-strand, and a 3'-exo conformation of the deoxyriboses for both sugar anomers. The three-dimensional structure obtained allowed us to describe the local heterogeneity of the duplex.     

Design considerations for array CGH to oligonucleotide arrays.

BACKGROUND: Representational oligonucleotide microarray analysis has been developed for detection of single nucleotide polymorphisms and/or for genome copy number changes. In this process, the intensity of hybridization to oligonucleotides arrays is increased by hybridizing a polymerase chain reaction (PCR)-amplified representation of reduced genomic complexity. However, hybridization to some oligonucleotides is not sufficiently high to allow precise analysis of that portion of the genome. METHODS: In an effort to identify aspects of oligonucleotide hybridization affecting signal intensity, we explored the importance of the PCR product strand to which each oligonucleotide is homologous and the sequence of the array oligonucleotides. We accomplished this by hybridizing multiple PCR-amplified products to oligonucleotide arrays carrying two sense and two antisense 50-mer oligonucleotides for each PCR amplicon. RESULTS: In some cases, hybridization intensity depended more strongly on the PCR amplicon strand (i.e., sense vs. antisense) than on the detection oligonucleotide sequence. In other cases, the oligonucleotide sequence seemed to dominate. CONCLUSION: Oligonucleotide arrays for analysis of DNA copy number or for single nucleotide polymorphism content should be designed to carry probes to sense and antisense strands of each PCR amplicon to ensure sufficient hybridization and signal intensity.     

Sequencing of oligonucleotide phosphorothioates based on solid-supported desulfurization.

We described a solid-supported desulfurization procedure allowing easy access to the sequence analysis of oligonucleotide phosphorothioates. The described method is based upon selective removal of the 2-cyanoethyl phosphate protecting groups, followed by iodine-promoted desulfurization of the resulting phosphorothioate diesters. Automatic oxidation of oligonucleotide phosphorothioates, anchored via an ester linkage to a standard solid support (LCAA/CPG), is combined with Maxam-Gilbert solid-support sequencing. The overall procedure allows rapid simultaneous sequence analysis of several oligonucleotide analogs.     

Novel method of the synthesis and hybridization properties of an oligonucleotide containing non-ionic diisopropylsilyl internucleotide linkage

Efficient synthesis of a dithymidine dinucleotide analog bearing a diisopropylsilyl linkage instead of a phosphodiester linkage is described with respect to its incorporation into oligonucleotides. The diisopropylsilyl linkage was introduced into the oligonucleotide by preparation of the phosphoramidite derivative of a dithymidine dimer unit. The diisopropylsilyl-modified oligonucleotide exhibited hybridization behavior with both single strand and duplex DNA. The thermal stability of both the duplex and triplex showed a relative instability compared to the corresponding natural phosphodiester DNA, because of the steric hindrance of the isopropyl group on the silicon atom.     

MagiProbe: a novel fluorescence quenching-based oligonucleotide probe carrying a fluorophore and an intercalator

Fluorescence is the favored signaling technology for molecular diagnoses. Fluorescence energy transfer-based methods are powerful homogeneous assay tools. A novel oligonucleotide probe, named MagiProbe, which is simple to use, is described, and information given about the duplex formed with a target. The probe internally has a fluorophore and an intercalator. Its fluorescence is quenched by the intercalator in the absence of a target sequence. On hybridization with a target sequence, the probe emits marked fluorescence due to the interference in quenching by intercalation. Furthermore, MagiProbe hybridized with a single-base mismatched target emits less fluorescence than with a perfect matched target. It therefore can detect a single base difference in a double-stranded form with a target.     

Duplex to quadruplex equilibrium of the self-complementary oligonucleotide d(GGGGCCCC)

The structure of the deoxyaligonucleotide d(GGGGCCCC) has been monitored by ¹H and ³¹ P NMR, and by gel electrophoresis. In low-salt solution, this oligonucleotide forms a stable duplex structure. Upon titration with KCl, an equilibrium is established between duplex and quadruplex forms. The quadruplex form is the dominant one at physiological KCl concentrations, despite the fact that fewer hydrogen bonds are formed per strand in the quadruplex than in the duplex. © 1995 John Wiley & Sons, Inc.