Interstrand cross-link formation in duplex and triplex DNA by modified pyrimidines

DNA interstrand cross-links have important biological consequences and are useful biotechnology tools. Phenylselenyl substituted derivatives of thymidine (1) and 5-methyl-2'-deoxycytidine (5) produce interstrand cross-links in duplex DNA when oxidized by NaIO4. The mechanism involves a [2,3]-sigmatropic rearrangement of the respective selenoxides to the corresponding methide type intermediates, which ultimately produce the interstrand cross-links. Determination of the rate constants for the selenoxide rearrangements indicates that the rate-determining step for cross-linking is after methide formation. Cross-linking by the thymidine derivative in duplex DNA shows a modest kinetic preference when flanked by pyrimidines as opposed to purines. In contrast, the rate constant for cross-link formation from 5 opposite dG in duplex DNA is strongly dependent upon the flanking sequence and, in general, is at least an order of magnitude slower than that for 1 in an otherwise identical sequence. Introduction of mispairs at the base pairs flanking 5 or substitution of the opposing dG by dI significantly increases the rate constant and yield for cross-linking, indicating that stronger hydrogen bonding between the methide derived from it and dG compared to dA and the respective electrophile derived from 1 limits reaction by increasing the barrier to rotation into the required syn-conformation. Incorporation of 1 or 5 in triplex forming oligonucleotides (TFOs) that utilize Hoogsteen base pairing also yields interstrand cross-links. The dC derivative produces ICLs approximately 10x faster than the thymidine derivative when incorporated at the 5'-termini of the TFOs and higher yields when incorporated at internal sites. The slower, less efficient ICL formation emanating from 1 is attributed to reaction at N1-dA, which requires local melting of the duplex. In contrast, 5 produces cross-links by reacting with N7-dG. The cross-linking reactions of 1 and 5 illustrate the versatility and utility of these molecules as mechanistic probes and tools for biotechnology.     

Synthesis and DNA triplex formation of an oligonucleotide containing an urocanamide

An urocanamide nucleoside designed and previously tested as its protected ribose derivative in aprotic solvents for binding a cytosine-guanine (CG) Watson-Crick base pair was successfully incorporated into a triplex forming oligonucleotide. Binding affinity and specificity of this nonnatural nucleoside were studied in a triple helix with duplex targets containing all four possible Watson-Crick base pairs opposite the nucleoside analog in the third strand. UV melting experiments indicate the formation of a well-defined triplex with specific binding of the urocanamide analog to a CG inversion of the homopurine-homopyrimidine target. However, binding affinities in the triplex are weak and much lower when compared to the canonical base triads.     

含有2'-O-甲基伪胞苷的寡核苷酸合成用于DNA三链的合成

三绞脱氧核糖核酸生成的可能性已知对双绞DNA的结构和功能有直接的影响,为增长三重态DNA生成的稳定性。我们设计并合成了2-氨基-5-(2-O-甲基-β-D-呋喃核糖基)-4(1H)-嘧啶酮或2'-O-甲基拟异胞嘧啶并取代第三股上的原来的碳。     

Photoregulation of RNA digestion by RNase H with azobenzene-tethered DNA

RNA digestion by RNase H, which is responsible for the antisense effect, was efficiently photoregulated by use of the duplex of azobenzene-tethered sense DNA and native antisense DNA. In the dark, RNA digestion was suppressed because antisense DNA was strongly hybridized with azobenzene-tethered sense DNA, and accordingly RNA was isolated. On UV irradiation, antisense DNA was released from the azobenzene-tethered DNA due to the trans-to-cis isomerization and hybridized with RNA, which was digested by RNase H.     

Direct photocleavage of HIV-DNA by quinacridine derivatives triggered by triplex formation

Amino-p-quinacridine compounds (PQs) have been shown to stabilize strongly and specifically triple-helical DNA. Moreover, these derivatives display photoactive properties that make them efficient DNA cleavage agents. We exploited these two properties (triplex-specific binding and photoactivity) to selectively cleave a double-stranded (ds)DNA sequence present in the HIV-1 genome. Cleavage was first carried out on a linearized plasmid (3300 bp) containing the HIV polypurine tract (PPT) that allowed targeting by a triplex-forming oligonucleotide (TFO). PQ(3)(), the most active compound of the series, efficiently cleaved double-stranded DNA in the vicinity of the PPT when this sequence had formed a triplex with a 16-mer TFO. Investigation of the cleavage at the molecular level was addressed on a short DNA fragment (56 bp); the photoinduced cleavage by PQ(3)() occurred only in the presence of the triple helix. Nevertheless, unusual cleavage patterns were observed: damage was observed at guanines located 6-9 bp away from the end of the triple helical site. This cleavage is very efficient (up to 60%), does not require alkaline treatment, and is observed on both strands. A quinacridine-TFO conjugate produced the same cleavage pattern. This observation, along with others, excludes the hypothesis of a triplex-induced allosteric binding site of PQ(3 )()adjacent to the damaged sequence and indicates that PQ(3 )()preferentially binds in the vicinity of the 5'-triplex junction. Irradiation in the presence of TFO-conjugates with acridine (an intercalative agent) and with the tripeptide lys-tryp-lys led to a complete inhibition of the photocleavage reaction. These results are interpreted in terms of competitive binding and of electron-transfer quenching. Together with the findings of simple mechanistic investigations, they led to the conclusion that the photoinduced damage proceeds through a direct electron transfer between the quinacridine and the guanines. This study addresses the chemical mechanism leading to strand breakage and characterizes the particular photosensitivity of the HIV-DNA target sequence which could be an oxidative hot spot for addressed photoinduced strand scission by photosensitizers.     

Alternate stranded triplex formation of chimeric DNA composed of tandem alpha- and beta-anomeric strands

A chimeric oligoDNA composed of a natural beta-anomeric oligonucleotide portion and an unnatural alpha-anomeric oligonucleotide portion forms an alternate stranded triplex possessing enhanced thermal stability compared to the triplexes composed of the parental oligomers.     

LNA functionalized gold nanoparticles as probes for double stranded DNA through triplex formation

Nanoparticle modified LNA probes have been used for colorimetric identification of double stranded DNA via parallel triplex formation, eliminating the need for prior denaturation of the target duplex.     

Molecular recognition via triplex formation of mixed purine/pyrimidine DNA sequences using oligoTRIPs

Stable DNA triple-helical structures are normally restricted to homopurine sequences. We have described a system of four heterocyclic bases (TRIPsides) that, when incorporated into oligomers (oligoTRIPs), can recognize and bind in the major groove to any native sequence of DNA [Li et al., J. Am. Chem. Soc. 2003, 125, 2084]. To date, we have reported on triplex-forming oligomers composed of two of these TRIPsides, i.e., antiTA and antiGC, and their ability to form intramolecular triplexes at mixed purine/pyrimidine sequences. In the present study, we describe the synthesis and characterization of the antiCG TRIPside and its use in conjunction with antiTA and antiGC to form sequence-specific intra- and/or intermolecular triplex structures at mixed purine/pyrimidine sequences that require as many as four major groove crossovers.     

Photoisomerization locking of azobenzene by formation of a self-assembled macrocycle

Reaction of an azobenzene-linked biscatecholate ligand with boron and titanium sources gave ring- and cage-shaped complexes in a self-assembly fashion, respectively. These complexes were inert to photoisomerization though the ligand itself was isomerized upon photoirradiation. The self-assembled macrocyclization caused inhibition of the photoisomerization.     

Polycation comb-type copolymer reduces counterion condensation effect to stabilize DNA duplex and triplex formation

We have previously demonstrated that the polycation comb-type copolymer having abundant grafts of hydrophilic polymer chains significantly stabilizes DNA duplexes and triplexes [Maruyama et al., Bioconjugate Chem., 8 (1997) 3, Ferdous et al., Nucleic Acids Res., 26 (1998) 39]. This study was designed to estimate the mechanisms involved in the copolymer-mediated stabilization of DNA duplexes and triplexes. The melting temperatures, T_m, of DNA duplex and triplex increased with increasing salt concentration, as well documented by the Poisson–Boltzmann and counterion condensation theories that were originally proposed by Manning [J. Chem. Phys., 51 (1969) 924] and further elaborated by Manning [Biopolymers 11 (1972) 937, Biopolymers. 15 (1976) 2385] and Record [Biopolymers, 14 (1975) 2137–2158, Biopolymers, 15 (1976) 893]. In the presence of the copolymer, however, the T_m values of DNA duplexes and triplexes did not show significant change with salt concentration. It was concluded that the copolymer is capable of reducing the counterion condensation effects to stabilize DNA duplexes and triplexes. Strong but exchangeable interaction between the copolymer and DNA is seemingly involved in the stabilization behavior.     

Sequence-specific control of azobenzene assemblies by molecular recognition of DNA

We investigated the molecular recognition between the amphiphile AzoAde, which is composed of azobenzene in the hydrophobic and adenine in the hydrophilic portion of the molecule, and oligonucleotides having a homogeneous base (dA30, dT30, dG30, and dC30) at the air-water interface. On the basis of the complementary base-pairing of DNA in the duplex, orderly arrangement of AzoAde on templated dT30 was examined using pi-A isotherm, UV-vis RAS, FT-IR RAS, and XPS measurements. Although there was little interaction between AzoAde and mismatched oligonucleotides (dA30, dG30, and dC30), AzoAde prepared on a dT30 subphase stoichiometrically assembled and interacted with dT30, subsequently forming a J-form assembly at the air-water interface. AFM observation of the LB films revealed the nanostructure of the J-formed AzoAde monolayer on the dT30 subphase as well as the domain structures of the H-formed monolayers on the other oligonucleotide subphases. Therefore, dT30 has a potential application as a template for assembling AzoAde at the air-water interface.     

光控DNA可逆杂交/解链及其应用

通过光敏分子与DNA相互作用,可以实现光控DNA杂交与解链,这种光控DNA有望成为下一代DNA功能构筑材料和纳米机械能量输入模式。本文总结了可逆光控DNA杂交/解链的各种途径及其作用机理,并分析其使用条件和光控效果。已有实验结果的对比和归纳表明,从DNA骨架上楔入含侧链偶氮苯官能团的单元,通过顺反异构实现DNA双链解链与杂交的可逆光控最具应用潜力,并且仍有一定的改进空间。本文介绍了这种骨架楔入偶氮苯光控DNA材料在纳米技术和生物技术方面的应用,并对其进一步的研究方向进行了展望。     

Structure of triplex DNA in the gas phase

Extensive (more than 90 microseconds) molecular dynamics simulations complemented with ion-mobility mass spectrometry experiments have been used to characterize the conformational ensemble of DNA triplexes in the gas phase. Our results suggest that the ensemble of DNA triplex structures in the gas phase is well-defined over the experimental time scale, with the three strands tightly bound, and for the most abundant charge states it samples conformations only slightly more compact than the solution structure. The degree of structural alteration is however very significant, mimicking that found in duplex and much larger than that suggested for G-quadruplexes. Our data strongly supports that the gas phase triplex maintains an excellent memory of the solution structure, well-preserved helicity, and a significant number of native contacts. Once again, a linear, flexible, and charged polymer as DNA surprises us for its ability to retain three-dimensional structure in the absence of solvent. Results argue against the generally assumed roles of the different physical interactions (solvent screening of phosphate repulsion, hydrophobic effect, and solvation of accessible polar groups) in modulating the stability of DNA structures.     

pH-Independent triplex formation: hairpin DNA containing isoguanine or 9-deaza-9-propynylguanine in place of protonated cytosine

Triplex-forming oligonucleotides (TFOs) containing 2'-deoxyisoguanosine (2), 7-bromo-7-deaza-2'-deoxyisoguanosine (2) as well as the propynylated 9-deazaguanine N7-(2'-deoxyribonucleoside) were prepared. For this the phosphoramidites 9a, b of the nucleoside 1 and, the phosphoramidites 19, 20 of compound 3b were synthesized. They were employed in solid-phase oligonucleotide synthesis to yield the protected 31-mer oligonucleotides. The deblocking of the allyl-protected oligonucleotides containing 1 was carried out by Pd(0)[PPh3]4-PPh3 followed by 25% aq. NH3. Formation of the 31-mer single-stranded intramolecular triplexes was studied by UV-melting curve analysis. In the single-stranded 31-mer oligonucleotides the protonated dC in the dCH(+)-dG-dC base triad was replaced by 2'-deoxyisoguanosine (1), 7-bromo-7-deaza-2'-deoxyisoguanosine (2) and, 9-deaza-9-propynylguanine N7-(2'-deoxyribonucleoside) (3b). The replacement of protonated dC by compounds 1 and 3b resulted in intramolecular triplexes which are formed pH-independently and are stable under neutral conditions. These triplexes contain "purine" nucleosides in the third pyrimidine rich strand of the oligonucleotide hairpin.