Recombination R-triplex: H-bonds contribution to stability as revealed with minor base substitutions for adenine

Several cellular processes involve alignment of three nucleic acids strands, in which the third strand (DNA or RNA) is identical and in a parallel orientation to one of the DNA duplex strands. Earlier, using 2-aminopurine as a fluorescent reporter base, we demonstrated that a self-folding oligonucleotide forms a recombination-like structure consistent with the R-triplex. Here, we extended this approach, placing the reporter 2-aminopurine either in the 5′- or 3′-strand. We obtained direct evidence that the 3′-strand forms a stable duplex with the complementary central strand, while the 5′-strand participates in non-Watson–Crick interactions. Substituting 2,6-diaminopurine or 7-deazaadenine for adenine, we tested and confirmed the proposed hydrogen bonding scheme of the A*(T·A) R-type triplet. The adenine substitutions expected to provide additional H-bonds led to triplex structures with increased stability, whereas the substitutions consistent with a decrease in the number of H-bonds destabilized the triplex. The triplex formation enthalpies and free energies exhibited linear dependences on the number of H-bonds predicted from the A*(T·A) triplet scheme. The enthalpy of the 10 nt long intramolecular triplex of −100 kJ·mol⁻¹ demonstrates that the R-triplex is relatively unstable and thus an ideal candidate for a transient intermediate in homologous recombination, t-loop formation at the mammalian telomere ends, and short RNA invasion into a duplex. On the other hand, the impact of a single H-bond, 18 kJ·mol⁻¹, is high compared with the overall triplex formation enthalpy. The observed energy advantage of a ‘correct’ base in the third strand opposite the Watson–Crick base pair may be a powerful mechanism for securing selectivity of recognition between the single strand and the duplex.     

Effect of DNA target sequence on triplex formation by oligo-2'-deoxy- and 2'-O-methylribonucleotides

The interactions of pyrimidine deoxyribo- or 2′-O-methylribo-psoralen-conjugated, triplex-forming oligonucleotides, psTFOs, with a 17-bp env-DNA whose purine tract is 5′-AGAGAGAAAAAAGAG-3′, or an 18-bp gag-DNA whose purine tract is 5′-AGG GGGAAAGAAAAAA-3′, were studied over the pH range 6.0–7.5. The stability of the triplex formed by a deoxy-env-psTFO containing 5-methylcytosines and thymines decreased with increasing pH (T_m = 56°C at pH 6.0; 27°C at pH 7.5). Replacement of 5-methylcytosines with 8-oxo-adenines reduced the pH dependence, but lowered triplex stability. A 2′-O-methyl-env-psTFO containing uracil and cytosine did not form a triplex at pH 7.5. Surprisingly, replacement of the cytosines in this oligomer with 5-methylcytosines dramatically increased triplex stability (T_m = 25°C at pH 7.5), and even greater stability was achieved by selective replacement of uracils with thymines (T_m = 37°C at pH 7.5). Substitution of the contiguous 5-methylcytosines of the deoxy-gag-psTFO with 8-oxo-adenines significantly reduced pH dependence and increased triplex stability. In contrast to the behavior of env-specific TFOs, triplexes formed by 2′-O-methyl-gag-psTFOs did not show enhanced stability. Replacement of the 3′-terminal phosphodiester of the TFO with a methylphosphonate group significantly increased the resistance of both deoxy- and 2′-O-methyl-TFOs to degradation by 3′-exonucleases, while maintaining triplex stability.     

Stabilizing contributions of sulfur-modified nucleotides: crystal structure of a DNA duplex with 2'-O-[2-(methoxy)ethyl]-2-thiothymidines

Substitution of oxygen atoms by sulfur at various locations in the nucleic acid framework has led to analogs such as the DNA phosphorothioates and 4′-thio RNA. The phosphorothioates are excellent mimics of DNA, exhibit increased resistance to nuclease degradation compared with the natural counterpart, and have been widely used as first-generation antisense nucleic acid analogs for applications in vitro and in vivo. The 4′-thio RNA analog exhibits significantly enhanced RNA affinity compared with RNA, and shows potential for incorporation into siRNAs. 2-Thiouridine (s²U) and 5-methyl-2-thiouridine (m⁵s²U) are natural nucleotide analogs. s²U in tRNA confers greater specificity of codon–anticodon interactions by discriminating more strongly between A and G compared with U. 2-Thio modification preorganizes the ribose and 2′-deoxyribose sugars for a C3′-endo conformation, and stabilizes heteroduplexes composed of modified DNA and complementary RNA. Combination of the 2-thio and sugar 2′-O-modifications has been demonstrated to boost both thermodynamic stability and nuclease resistance. Using the 2′-O-[2-(methoxy)ethyl]-2-thiothymidine (m⁵s²Umoe) analog, we have investigated the consequences of the replacement of the 2-oxygen by sulfur for base-pair geometry and duplex conformation. The crystal structure of the A-form DNA duplex with sequence GCGTAT*ACGC (T* = m⁵s²Umoe) was determined at high resolution and compared with the structure of the corresponding duplex with T* = m⁵Umoe. Notable changes as a result of the incorporation of sulfur concern the base-pair parameter ‘opening’, an improvement of stacking in the vicinity of modified nucleotides as measured by base overlap, and a van der Waals interaction between sulfur atoms from adjacent m⁵s²Umoe residues in the minor groove. The structural data indicate only minor adjustments in the water structure as a result of the presence of sulfur. The observed small structural perturbations combined with the favorable consequences for pairing stability and nuclease resistance (when combined with 2′-O-modification) render 2-thiouracil-modified RNA a promising candidate for applications in RNAi.     

Triplex-forming properties and enzymatic incorporation of a base-modified nucleotide capable of duplex DNA recognition at neutral pH

The sequence-specific recognition of duplex DNA by unmodified parallel triplex-forming oligonucleotides is restricted to low pH conditions due to a necessity for cytosine protonation in the third strand. This has severely restricted their use as gene-targeting agents, as well as for the detection and/or functionalisation of synthetic or genomic DNA. Here I report that the nucleobase 6-amino-5-nitropyridin-2-one (Z) finally overcomes this constraint by acting as an uncharged mimic of protonated cytosine. Synthetic TFOs containing the nucleobase enabled stable and selective triplex formation at oligopurine-oligopyrimidine sequences containing multiple isolated or contiguous GC base pairs at neutral pH and above. Moreover, I demonstrate a universal strategy for the enzymatic assembly of Z-containing TFOs using its commercially available deoxyribonucleotide triphosphate. These findings seek to improve not only the recognition properties of TFOs but also the cost and/or expertise associated with their chemical syntheses.     

Remarkable stabilization of antiparallel DNA triplexes by strong stacking effects of consecutively modified nucleobases containing thiocarbonyl groups

The consecutive arrangement of 2′-deoxy-6-thioguanosines (s⁶Gs) and 4-thiothymidines (s⁴Ts) in antiparallel triplex-forming oligonucleotides (TFOs) considerably stabilized the resulting antiparallel triplexes with high base recognition ability by the strong stacking effects of thiocarbonyl groups. This result was remarkable because chemical modifications of the sugar moieties and nucleobases of antiparallel TFOs generally destabilize triplex structures. Moreover, in comparison with unmodified TFOs, it was found that TFOs containing s⁶Gs and s⁴Ts could selectively bind to the complementary DNA duplex but not to mismatched DNA duplexes or single-stranded RNA.     

Optimal design of parallel triplex forming oligonucleotides containing Twisted Intercalating Nucleic Acids—TINA

Twisted intercalating nucleic acid (TINA) is a novel intercalator and stabilizer of Hoogsteen type parallel triplex formations (PT). Specific design rules for position of TINA in triplex forming oligonucleotides (TFOs) have not previously been presented. We describe a complete collection of easy and robust design rules based upon more than 2500 melting points (T_m) determined by FRET. To increase the sensitivity of PT, multiple TINAs should be placed with at least 3 nt in-between or preferable one TINA for each half helixturn and/or whole helixturn. We find that ΔT_m of base mismatches on PT is remarkably high (between 7.4 and 15.2°C) compared to antiparallel duplexes (between 3.8 and 9.4°C). The specificity of PT by ΔT_m increases when shorter TFOs and higher pH are chosen. To increase ΔTms, base mismatches should be placed in the center of the TFO and when feasible, A, C or T to G base mismatches should be avoided. Base mismatches can be neutralized by intercalation of a TINA on each side of the base mismatch and masked by a TINA intercalating direct 3′ (preferable) or 5′ of it. We predict that TINA stabilized PT will improve the sensitivity and specificity of DNA based clinical diagnostic assays.     

Four base recognition by triplex-forming oligonucleotides at physiological pH

We have achieved recognition of all 4 bp by triple helix formation at physiological pH, using triplex-forming oligonucleotides that contain four different synthetic nucleotides. BAU [2′-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine] recognizes AT base pairs with high affinity, ^MeP (3-methyl-2 aminopyridine) binds to GC at higher pHs than cytosine, while ^APP (6-(3-aminopropyl)-7-methyl-3H-pyrrolo[2,3-d]pyrimidin-2(7H)-one) and S [N-(4-(3-acetamidophenyl)thiazol-2-yl-acetamide)] bind to CG and TA base pairs, respectively. Fluorescence melting and DNase I footprinting demonstrate successful triplex formation at a 19mer oligopurine sequence that contains two CG and two TA interruptions. The complexes are pH dependent, but are still stable at pH 7.0. BAU, ^MeP and ^APP retain considerable selectivity, and single base pair changes opposite these residues cause a large reduction in affinity. In contrast, S is less selective and tolerates CG pairs as well as TA.     

Sequence-dependent formation of intrastrand crosslink products from the UVB irradiation of duplex DNA containing a 5-bromo-2'-deoxyuridine or 5-bromo-2'-deoxycytidine

The replacement of thymidine with 5-bromo-2′-deoxyuridine (^BrdU) is well-known to sensitize cells to ionizing radiation and photoirradiation. We reported here the sequence-dependent formation of intrastrand crosslink products from the UVB irradiation of duplex oligodeoxynucleotides harboring a ^BrdU or its closely related 5-bromo-2′-deoxycytidine (^BrdC). Our results showed that two types of crosslink products could be induced from d(^BrCG), d(^BrUG), d(G^BrU), or d(A^BrU); the C(5) of cytosine or uracil could be covalently bonded to the N(2) or C(8) of its neighboring guanine, and the C(5) of uracil could couple with the C(2) or C(8) of its neighboring adenine. By using those crosslink product-bearing dinucleoside monophosphates as standards, we demonstrated, by using liquid chromatography-mass spectrometry/mass spectrometry (LC-MS/MS), that all the crosslink products described above except d(G[N(2)-5]U) and d(G[N(2)-5]C) could form in duplex DNA. In addition, LC-MS/MS quantification results revealed that both the nature of the halogenated pyrimidine base and its 5′ flanking nucleoside affected markedly the generation of intrastrand crosslink products. The yields of crosslink products were much higher while the 5′ neighboring nucleoside was a dG than while it was a dA, and ^BrdC induced the formation of crosslink products much more efficiently than ^BrdU. The formation of intrastrand crosslink products from these halopyrimidines in duplex DNA may account for the photosensitizing effects of these nucleosides.     

Parallel intramolecular DNA triple helix with G and T bases in the third strand stabilized by Zn(2+) ions

We present evidence of formation of an intramolecular parallel triple helix with T•A.T and G•G.C base triplets (where • represents the hydrogen bonding interaction between the third strand and the duplex while . represents the Watson–Crick interactions which stabilize the duplex). The third GT strand, containing seven GpT/TpG steps, targets the polypurine sequence 5′-AGG-AGG-GAG-GAG-3′. The triple helix is obtained by the folding back twice of a 36mer, formed by three dodecamers tethered by hydroxyalkyl linkers (-L-). Due to the design of the oligonucleotide, the third strand orientation is parallel with respect to the polypurine strand. Triple helical formation has been studied in concentration conditions in which native gel electrophoresis experiments showed the absence of intermolecular structures. Circular dichroism (CD) and UV spectroscopy have been used to evidence the triplex structure. A CD spectrum characteristic of triple helical formation as well as biphasic UV and CD melting curves have been obtained in high ionic strength NaCl solutions in the presence of Zn²⁺ ions. Specific interactions with Zn²⁺ ions in low water activity conditions are necessary to stabilize the parallel triplex.     

Efficient processing of TFO-directed psoralen DNA interstrand crosslinks by the UvrABC nuclease

Photoreactive psoralens can form interstrand crosslinks (ICLs) in double-stranded DNA. In eubacteria, the endonuclease UvrABC plays a key role in processing psoralen ICLs. Psoralen-modified triplex-forming oligonucleotides (TFOs) can be used to direct ICLs to specific genomic sites. Previous studies of pyrimidine-rich methoxypsoralen–modified TFOs indicated that the TFO inhibits cleavage by UvrABC. Because different chemistries may alter the processing of TFO-directed ICLs, we investigated the effect of another type of triplex formed by purine-rich TFOs on the processing of 4′-(hydroxymethyl)-4,5′,8-trimethylpsoralen (HMT) ICLs by the UvrABC nuclease. Using an HMT-modified TFO to direct ICLs to a specific site, we found that UvrABC made incisions on the purine-rich strand of the duplex ~3 bases from the 3′-side and ~9 bases from the 5′-side of the ICL, within the TFO-binding region. In contrast to previous reports, the UvrABC nuclease cleaved the TFO-directed psoralen ICL with a greater efficiency than that of the psoralen ICL alone. Furthermore, the TFO was dissociated from its duplex binding site by UvrA and UvrB. As mutagenesis by TFO-directed ICLs requires nucleotide excision repair, the efficient processing of these lesions supports the use of triplex technology to direct DNA damage for genome modification.     

Position- and orientation-specific enhancement of topoisomerase I cleavage complexes by triplex DNA structures

Topoisomerase I (Top1) activities are sensitive to various endogenous base modifications, and anticancer drugs including the natural alkaloid camptothecin. Here, we show that triple helix-forming oligonucleotides (TFOs) can enhance Top1-mediated DNA cleavage by affecting either or both the nicking and the closing activities of Top1 depending on the position and the orientation of the triplex DNA structure relative to the Top1 site. TFO binding 1 bp downstream from the Top1 site enhances cleavage by inhibiting religation and to a lesser extent DNA nicking. In contrast, TFO binding 4 bp downstream from the Top1 site enhances DNA nicking especially when the 3′ end of the TFO is proximal to the Top1 site. However, when the orientation of the triplex is inverted, with its 5′ terminus 4 bp downstream from the Top1 site, religation is also inhibited. These position- and orientation-dependent effects of triplex structures on the Top1-mediated DNA cleavage and religation are discussed in the context of molecular modeling and effects of TFO on DNA twist and mobility at the duplex/triplex junction.     

Novel Hoogsteen-like Bases for Recognition of the C-G Base Pair by DNA Triplex Formation

Effective sequence-specific recognition of duplex DNA is possible by triplex formation with natural oligonucleotides via Hoogsteen H-bonding. However, triplex formation is in practice limited to pyrimidine oligonucleotides that bind duplex A-T or G-C base pair DNA sequences specifically at homopurine sites in the major groove as T·A-T and C⁺ ·G-C triplets. Here we report the successful modelling of novel unnatural nucleosides that recognize the C-G DNA base pair by Hoogsteen-like major groove interaction. These novel Hoogsteen nucleotides are examined within model A-type and B-type conformation triplex structures since the DNA triplex can be considered to incorporate A-type and/or B-type configurational properties. Using the same deoxyribose-phosphodiester and base-deoxyribose dihedral angle configuration, a triplet comprised of a C-G base pair and the novel Hoogsteen nucleotide, Y2, replaces the central T·A-T triplet in the triplex. The presence of any structural or energetic perturbations due to the central triplet in the energy-minimized triplex is assessed with respect to the unmodified energy minimized (T·A-T)₁₁ starting structures. Incorporation of this novel triplet into both A-type and B-type natural triplex structures provokes minimal change in the configuration of the central and adjacent triplets.     

Clamping down on weak terminal base pairs: oligonucleotides with molecular caps as fidelity-enhancing elements at the 5'- and 3'-terminal residues

The base-pairing fidelity of oligonucleotides depends on the identity of the nucleobases involved and the position of matched or mismatched base pairs in the duplex. Nucleobases forming weak base pairs, as well as a terminal position favor mispairing. We have searched for 5′-appended acylamido caps that enhance the stability and base-pairing fidelity of oligonucleotides with a 5′-terminal 2′-deoxyadenosine residue using combinatorial synthesis and MALDI-monitored nuclease selections. This provided the residue of 4-(pyren-1-yl)butyric acid as a lead. Lead optimization gave (S)-N-(pyren-1-ylmethyl)pyrrolidine-3-phosphate as a cap that increases duplex stability and base-pairing fidelity. For the duplex of 5′-AGGTTGAC-3′ with its fully complementary target, this cap gives an increase in the UV melting point T_m of +10.9°C. The T_m is 6.3–8.3°C lower when a mismatched nucleobase faces the 5′-terminal dA residue. The optimized cap can be introduced via automated DNA synthesis. It was combined with an anthraquinone carboxylic acid residue as a cap for the 3′-terminal residue. A doubly capped dodecamer thus prepared gives a melting point decrease for double-terminal mismatches that is 5.7–5.9°C greater than that for the unmodified control duplex.     

Triplex-induced recombination and repair in the pyrimidine motif

Triplex-forming oligonucleotides (TFOs) bind DNA in a sequence-specific manner at polypurine/polypyrimidine sites and mediate targeted genome modification. Triplexes are formed by either pyrimidine TFOs, which bind parallel to the purine strand of the duplex (pyrimidine, parallel motif), or purine TFOs, which bind in an anti-parallel orientation (purine, anti-parallel motif). Both purine and pyrimidine TFOs, when linked to psoralen, have been shown to direct psoralen adduct formation in cells, leading to mutagenesis or recombination. However, only purine TFOs have been shown to mediate genome modification without the need for a targeted DNA-adduct. In this work, we report the ability of a series of pyrimidine TFOs, with selected chemical modifications, to induce repair and recombination in two distinct episomal targets in mammalian cells in the absence of any DNA-reactive conjugate. We find that TFOs containing N3′→P5′ phosphoramidate (amidate), 5-(1-propynyl)-2′-deoxyuridine (pdU), 2′-O-methyl-ribose (2′-O-Me), 2′-O-(2-aminoethyl)-ribose, or 2′-O, 4′-C-methylene bridged or locked nucleic acid (LNA)-modified nucleotides show substantially increased formation of non-covalent triplexes under physiological conditions compared with unmodified DNA TFOs. However, of these modified TFOs, only the amidate and pdU-modified TFOs mediate induced recombination in cells and stimulate repair in cell extracts, at levels comparable to those seen with purine TFOs in similar assays. These results show that amidate and pdU-modified TFOs can be used as reagents to stimulate site-specific gene targeting without the need for conjugation to DNA-reactive molecules. By demonstrating the potential for induced repair and recombination with appropriately modified pyrimidine TFOs, this work expands the options available for triplex-mediated gene targeting.     

Recognition of CG interrupting site by W-shaped nucleoside analogs (WNA) having the pyrazole ring in an anti-parallel triplex DNA

We have previously developed W-shaped nucleoside analogs (WNA) for recognition of TA and CG interrupting sites, which are the intrinsic limitation for the formation of a stable triplex DNA by the natural triplex-forming oligonucleotide (TFO). However, the stabilization effect of WNA is dependent on the neighboring nucleobases at both sides of the WNA analogs within the TFO. Considering that the base is located at the hindered site constructed of three bases of the target duplex and the TFO, it was expected that replacement of the pyrimidine base of the WNA analog with a smaller pyrazole ring might avoid steric repulsion to produce a greater stability for the triplex. In this study, the new WNA analogs bearing the pyrazole ring, 3-aminopyrazole (AP), and 4-methyl-3-pyrazole-5-on (MP) were synthesized, incorporated into the TFOs, then their stabilizing effects on the triplexes were evaluated. A remarkable success was illustrated by the fact that the TFO containing WNA-βAP in the 3′G-WNA-G-5′ sequence formed a stable triplex with selectivity to the CG interrupting site where the previous WNA-βC did not induce the triplex formation.     

Synthesis and monitored selection of nucleotide surrogates for binding T:A base pairs in homopurine-homopyrimidine DNA triple helices

A total of 16 oligodeoxyribonucleotides of general sequence 5′-TCTTCTZTCTTTCT-3′, where Z denotes an N-acyl-N-(2-hydroxyethyl)glycine residue, were prepared via solid phase synthesis. The ability of these oligonucleotides to form triplexes with the duplex 5′-AGAAGATAGAAAGA-HEG-TCTTTCTATCTTCT-3′, where HEG is a hexaethylene glycol linker, was tested. In these triplexes, an ‘interrupting’ T:A base pair faces the Z residue in the third strand. Among the acyl moieties of Z tested, an anthraquinone carboxylic acid residue linked via a glycinyl group gave the most stable triplex, whose UV melting point was 8.4°C higher than that of the triplex with 5′-TCTTCTGTCTTTCT-3′ as the third strand. The results from exploratory nuclease selection experiments suggest that a combinatorial search for strands capable of recognizing mixed sequences by triple helix formation is feasible.     

Factors influencing the extent and selectivity of alkylation within triplexes by reactive G/A motif oligonucleotides.

G/A motif triplex-forming oligonucleotides (TFOs) complementary to a 21 base pair homopurine/homopyrimidine run were conjugated at one or both ends to chlorambucil. These TFOs were incubated with several synthetic duplexes containing the targeted homopurine run flanked by different sequences. The extent of mono and interstrand cross-linking was compared with the level of binding at equilibrium. Covalent modification took place within a triple-stranded complex and usually occurred at guanine residues in the flanking double-stranded DNA. The efficiency of alkylation was dependent upon the sequence of the flanking duplex, the solution conditions, and the rate of triplex formation relative to the rate of chlorambucil reaction. Self-association of the TFOs as parallel duplexes was demonstrated and this did not interfere with triple strand formation. With an optimal target, cross-linking of the triplex was very efficient when incubation was carried in a physiological buffer supplemented with the triplex selective intercalator coralyne.