Watson-Crick Strand Research Articles

Parallel Clamps and Polypurine Hairpins (PPRH) for Gene Silencing and Triplex-Affinity Capture: Design, Synthesis, and Use.

Nucleic acid triplexes are formed when a DNA or RNA oligonucleotide binds to a polypurine-polypyrimidine-rich sequence. Triplexes have wide therapeutic applications such as gene silencing or site-specific mutagenesis. In addition, protocols based on triplex-affinity capture have been used for detecting nucleic acids in biosensing platforms. In this article, the design, synthesis, and use of parallel clamps and polypurine-reversed hairpins (PPRH) to bind to target polypyrimidine targets are described. The combination of the polypurine Watson-Crick strand with the triplex-forming strand in a single molecule produces highly stable triplexes allowing targeting of single- and double-stranded nucleic acid sequences. On the other hand, PPRHs are easily prepared and work at nanomolar range, like siRNAs, and at a lower concentration than that needed for antisense ODNs or TFOs. However, the stability of PPRHs is higher than that of siRNAs. In addition, PPRHs circumvent off-target effects and are non-immunogenic. © 2019 by John Wiley & Sons, Inc.

Anti-parallel triplexes: Synthesis of 8-aza-7-deazaadenine nucleosides with a 3-aminopropynyl side-chain and its corresponding LNA analog

The phosphoramidites of DNA monomers of 7-(3-aminopropyn-1-yl)-8-aza-7-deazaadenine (Y) and 7-(3-aminopropyn-1-yl)-8-aza-7-deazaadenine LNA (Z) are synthesized, and the thermal stability at pH 7.2 and 8.2 of anti-parallel triplexes modified with these two monomers is determined. When, the anti-parallel TFO strand was modified with Y with one or two insertions at the end of the TFO strand, the thermal stability was increased 1.2°C and 3°C at pH 7.2, respectively, whereas one insertion in the middle of the TFO strand decreased the thermal stability 1.4°C compared to the wild type oligonucleotide. In order to be sure that the 3-aminopropyn-1-yl chain was contributing to the stability of the triplex, the nucleobase X without the aminopropynyl group was inserted in the same positions. In all cases the thermal stability was lower than the corresponding oligonucleotides carrying the 3-aminopropyn-1-yl chain, especially at the end of the TFO strand. On the other hand, the thermal stability of the anti-parallel triplex was dramatically decreased when the TFO strand was modified with the LNA monomer analog Z in the middle of the TFO strand (ΔTm=−9.1°C). Also the thermal stability decreased about 6.1°C when the TFO strand was modified with Z and the Watson–Crick strand with adenine-LNA (AL). The molecular modeling results showed that, in case of nucleobases Y and Z a hydrogen bond (1.69 and 1.72Ǻ, respectively) was formed between the protonated 3-aminopropyn-1-yl chain and one of the phosphate groups in Watson–Crick strand. Also, it was shown that the nucleobase Y made a good stacking and binding with the other nucleobases in the TFO and Watson–Crick duplex, respectively. In contrast, the nucleobase Z with LNA moiety was forced to twist out of plane of Watson–Crick base pair which is weakening the stacking interactions with the TFO nucleobases and the binding with the duplex part.

Interaction of 9-O-(ω-amino) alkyl ether berberine analogs with poly(dT)·poly(dA)*poly(dT) triplex and poly(dA)·poly(dT) duplex: a comparative study

Isoquinoline alkaloids and their analogs represent an important class of molecules for their broad range of clinical and pharmacological utility. These compounds are of current interest owing to their low toxicity and excellent chemo preventive properties. These alkaloids can play important role in stabilising the nucleic acid triple helices. The present study has focused on the interaction of five 9-O-(ω-amino) alkyl ether berberine analogs with the DNA triplex poly(dT)·poly(dA)*poly(dT) and the parent duplex poly(dA)·poly(dT) studied using various biophysical techniques. Scatchard analysis of the spectral data indicated that the analogs bind both to the duplex and triplex in a non-cooperative manner in contrast to the cooperative binding of berberine to the DNA triplex. Strong intercalative binding to the DNA triplex structure was revealed from ferrocyanide quenching, fluorescence polarization and viscosity results. Thermal melting studies demonstrated higher stabilization of the Hoogsteen base paired third strand of the DNA triplex compared to the Watson-Crick strand. Circular dichroism studies suggested a stronger perturbation of the DNA triplex conformation by the alkaloid analogs compared to the duplex. The binding was entropy-driven in each case and the entropy contribution to free energy increased as the length of the alkyl side chain increased. The analogs exhibited stronger binding affinity to the triple helical structure compared to the parent double helical structure.

Theoretical Study of the Guanine → 6-Thioguanine Substitution in Duplexes, Triplexes, and Tetraplexes

Molecular dynamics and thermodynamic integration calculations have been carried out on a set of G-rich single-strand, duplex, triplex, and quadruplex DNAs to study the structural and stability changes connected with the guanine --> 6-thioguanine (G --> S) mutation. The presence of 6-thioguanine leads to a shift of the geometry from the B/A intermediate to the pure B-form in duplex DNA. The G --> S mutation does not largely affect the structure of the antiparallel triplex when it is located at the reverse-Hoogsteen position, but leads to a non-negligible local distortion in the structure when it is located at the Watson-Crick position. The G --> S mutation leads to destabilization of all studied structures: the lowest effect has been observed for the G --> S mutation in the reverse-Hoogsteen strand of the triplex, a medium effect has been observed in the Watson-Crick strand of the triplex and duplex, and the highest influence of the G -->S mutation has been found for the quadruplex structures.

Spectroscopic and Thermodynamic Studies on the Binding of Sanguinarine and Berberine to Triple and Double Helical DNA and RNA Structures

A comparative study on the interaction of sanguinarine and berberine with DNA and RNA triplexes and their parent duplexes was performed, by using a combination of spectrophotometric, UV thermal melting, circular dichroic and thermodynamic techniques. Formation of the DNA and RNA triplexes was confirmed from UV-melting and circular dichroic measurements. The interaction process was characterized by increase of thermal melting temperature, perturbation in circular dichroic spectrum and the typical hypochromic and bathochromic effects in the absorption spectrum. Scatchard analysis indicated that both the alkaloids bound to the triplex and duplex structures in a non-cooperative manner and the binding was stronger to triplexes than to parent duplexes. Thermal melting studies further indicated that sanguinarine stabilized the Hoogsteen base paired third strand of both DNA and RNA triplexes more tightly compared to their Watson-Crick strands, while berberine stabilized the third strand only without affecting the Watson-Crick strand. However, sanguinarine stabilized the parent duplexes while no stabilization was observed with berberine under identical conditions. Circular dichroic studies were also consistent with the observation that perturbations of DNA and RNA triplexes were more compared to their parent duplexes in presence of the alkaloids. Thermodynamic data revealed that binding of sanguinarine and berberine to triplexes (T·AxT and U·AxU) and duplexes (A·T and A·U) showed negative enthalpy changes and positive entropy changes but that of sanguinarine to C·GxC+ triplex and G·C duplex exhibited negative enthalpy and negative entropy changes. Taken together, these results suggest that both sanguinarine and berberine can bind and stabilize the DNA and RNA triplexes more strongly than their respective parent duplexes.

Observation of Spontaneous Base Pair Breathing Events in the Molecular Dynamics Simulation of a Difluorotoluene-Containing DNA Oligonucleotide

Observation of Spontaneous Base Pair Breathing Events in the Molecular Dynamics Simulation of a Difluorotoluene-Containing DNA Oligonucleotide

Peptide nucleic acids (PNA) derived from N-(N-methylaminoethyl)glycine. Synthesis, hybridization and structural properties

Backbone N-methylated peptide nucleic acids (PNAs) containing the four nucleobases adenine, cytosine, guanine and thymine were synthesized via solid phase peptide oligomerization. The oligomers bind to their complementary target with a thermal stability that is 1.5–4.5°C lower per '‘N-methyl nucleobase unit’' [dependent on the number and position(s) of the N-methyl] than that of unmodified PNA. However, even fully N-methyl modified PNAs bind as efficiently to DNA or RNA targets as DNA itself. Furthermore, the hybridization efficiency per N-methyl unit in a PNA decreased with increasing N-methyl content, and the effect was more pronounced when the N-methyl backbone units are present in the Hoogsteen versus the Watson–Crick strand in (PNA)2-DNA triplexes. Interestingly, CD spectral analyses indicate that 30% (3 out of ten) substitution with N-methyl nucleobases did not alter the structure of PNA-DNA (or RNA) duplexes or (PNA)2-DNA triplexes, and likewise CD spectroscopy and X-ray crystallography showed no major structural differences between N-methylated (30%) and unmodified PNA-PNA duplexes. However, PNA-DNA duplexes as well as triplexes adopted a different conformation when formed with all-N-methyl PNAs.

Stereoselectivity of Human Nucleotide Excision Repair Promoted by Defective Hybridization

To assess helical parameters that dictate fast or slow removal of carcinogen-DNA adducts, we probed human nucleotide excision repair (NER) activity with DNA containing L-deoxyriboses. Unlike natural lesions such as pyrimidine dimers or base adducts, L-deoxyribonucleosides (the mirror images of normal D-deoxyribonucleosides) involve neither the addition nor the loss of covalent bonds or functional groups and hence exclude modulation of repair efficiency by adduct chemistry and size. Previous studies showed that single L-deoxyribonucleosides distort DNA backbones but are accommodated in the double helix with intact hydrogen bonding between complementary strands. Here, we found that such single L-enantiomers are rejected as excision repair substrates in a NER-proficient cell extract. However, the same L-deoxyribose moiety stimulates NER activity upon incorporation into a nonhybridizing site of one or, more effectively, two base mismatches. In contrast to single L-deoxyriboses, multiple consecutive L-deoxyriboses interfere with normal hybridization; in this case, the intrinsic derangement of base pairing was sufficient to promote the excision of a cluster of three adjacent L-deoxyribonucleosides without any requirement for mismatches. Thus, using stereoselective substrates, we demonstrate the participation of a recognition subunit that guides human NER activity to sites of defective Watson-Crick strand pairing. This conformational sensor detects labile hydrogen bonds irrespective of the type of deoxyribonucleotide modification.

Rh(phen)2phi3+ as a shape-selective probe of triple helices.

RNA pur*pur-pyr and pyr*pur-pyr (pur = purine, pyr = pyrimidine) triple helices consisting of a Watson-Crick base-paired 28mer hairpin duplex and a Hoogsteen base-paired purine or pyrimidine 12mer are targeted with photoactivated cleavage by the metal complex Rh(phen)2phi3+ (phen = phenanthroline, phi = 9, 10-phenanthrenequinone diimine). The metal complex interacts with these triple helices in a structure-specific manner. Different cleavage patterns are seen with the pyr*pur-pyr and pur*pur-pyr motifs. Cleavage is seen on both of the Watson-Crick strands of the former motif and primarily on the purine Watson-Crick strand of the latter motif. Little cleavage is seen on the Hoogsteen strand for either motif. Importantly, the metal complex shows no detectable cleavage on the A-form RNA duplex in the absence of the third Hoogsteen strand. The cleavage patterns are consistent with an intercalated model for the metal complex in the triple helix. Similar cleavage is seen on DNA triple helices, but over a background of duplex cleavage. Targeting of synthetic RNA triple helices, but not duplex regions, by Rh(phen)2phi3+ provides a basis for the chemical probing of triply bonded sites in folded RNA molecules.

Design of an N7-Glycosylated Purine Nucleoside for Recognition of GC Base Pairs by Triple Helix Formation

Pyrimidine oligodeoxyribonucleotides bind in the major groove of DNA parallel to the purine Watson-Crick strand by formation of specific hydrogen bonds between thymine and adenine (T•AT triplet) and protonated cytosine and guanine (C+GC triplet) on the Hoogsteen face of the purine base. Alternatively, purine oligodeoxyribonucleotides bind in an antiparallel orientation relative to the purine Watson-Crick strand by formation of G•GC and A•AT triplets. The prerequisite protonation of cytosine in C+GC triplets leads to a considerable pH dependence in the binding affinity of C-containing oligodeoxyribonucleotides (Figure 1). Substitution of 5-methylcytosine (^mC) for cytosine results in increased binding affinities near physiological pH. In an attempt to eliminate the necessity for protonation, recent efforts have been directed toward the synthesis of nonnatural nucleosides which display the hydrogen bonding functionality of protonated cytosine.

Sequence-specific recognition of double helical RNA and RNA.DNA by triple helix formation.

The stabilities of eight triple helical pyrimidine.purine.pyrimidine structures comprised of identical sequence but different RNA (R) or DNA (D) strand combinations were measured by quantitative affinity cleavage titration. The differences in equilibrium binding affinities reveal the importance of strand composition. For the sequences studied here, the stabilities of complexes containing a pyrimidine third strand D or R and purine.pyrimidine double helical DD, DR, RD, and RR decrease in order: D + DD, R + DD, R + DR, D + DR > R + RD, R + RR >> D + RR, D + RD (pH 7.0, 25 degrees C, 100 mM NaCl/1 mM spermine). These findings suggest that RNA and DNA oligonucleotides will be useful for targeting (i) double helical DNA and (ii) RNA.DNA hybrids if the purine Watson-Crick strand is DNA. However, RNA, but not DNA, oligonucleotides will be useful for sequence-specific binding of (i) double helical RNA and (ii) RNA.DNA hybrids if the purine Watson-Crick strand is RNA. This has implications for the design of artificial ligands targeted to specific sequences of double helical RNA and RNA.DNA hybrids.

Inhibition of gene transcription by purine rich triplex forming oligodeoxyribonucleotides.

Several oligodeoxynucleotides (ODNs) were designed in order to interact with the purine rich element of the IRE (Interferon Responsive Element) of the 6-16 gene by triplex formation. An ODN of 21 bases, the sequence being identical to that of the purine strand of the IRE (48% G), but in reverse orientation, was able to interact with the IRE (KD: 20 nM). The binding was Mg2+ dependent. The two purine strands of the triplex were oriented antiparallel as confirmed by DNAase I and copper-phenanthroline footprinting experiments. An ODN in which A were replaced by T, also interacted with the same target, but with a lower affinity. Exonuclease III action indicated that the two IRE repeats of the 6-16 promoter interacted with each other through Hoogsteen base pairing, the third strand being parallel to the paired Watson-Crick strand. This led to a potential H-DNA structure which could be destabilized by adding ODNs able to form a triplex structure. 6-16 IRE driven-reporter gene constructs lost their interferon stimulability when co-transfected with triplex forming ODNs. The range of effective ODN concentrations was compatible with the affinity determined when measuring their direct interactions with the DNA.