Relative efficiencies of CpM(CO)(n)CH(3) and CpM(CO)(n)Ph (M = Cr,Mo, W,and Fe) complexes in photoinduced DNA cleavage

The relative efficiencies of photoinduced DNA cleavage by complexes of the type CpM(CO)(n)()R (M = Cr, Mo, or W, n = 3, R = CH(3) or Ph; M = Fe, n = 2, R = CH(3) or C(6)H(5)) have been investigated using a plasmid relaxation assay. Only the tungsten and iron complexes reproducibly caused single strand scission, in addition to which the iron systems efficiently gave double strand cleavage. The iron complexes gave strand scission at lower concentrations than the corresponding tungsten systems, with the phenyl complexes producing more damage than the methyl systems.     

A ribose sugar conformational switch in the LTR-retrotransposon Ty3 polypurine tract-containing RNA/DNA hybrid

To probe structural features of a polypurine tract (PPT) that mediate its specific recognition and processing, a model 20 bp RNA/DNA hybrid duplex, which includes the full PPT sequence of the Saccharomyces cerevisiae LTR-retrotransposon Ty3, has been investigated using solution NMR spectroscopy. While homonuclear NOESY and DQF-COSY analyses indicate that this PPT-containing RNA/DNA hybrid adopts an overall A-form-like helical geometry, an unexpected sugar pucker switch has been detected for the ribose at position +1, relative to the cleavage site, on the RNA strand. A model of the conformational changes induced by the A- to B-type sugar pucker switch shows a significant change in the backbone trajectory of the RNA strand, which alters the presentation of backbone phosphate and 2' hydroxyl groups 3' of this residue. This observation implies that part of the mechanism governing RNase H fidelity may be through distortion of the RNA/DNA helix one base ahead of the scissile bond.     

Selective photocleavage of DNA and RNA by anthraquinone derivatives: targeting the single-strand region of hairpin structures

A tetracationic anthraquinone derivative (27AQS2) binds to hairpin DNA and RNA. Ultraviolet irradiation of the bound quinone causes cleavage in the loop region of both oligonucleotides and at guanines in the stem region of the DNA hairpin. The absence of observable strand cleavage at guanines in the RNA hairpin suggests that either aniline treatment does not cause cleavage at damaged guanines in RNA or that radical cation migration does not occur readily in RNA duplexes. The ability to target the single-stranded regions of DNA and RNA structures is an important property of this photonuclease.     

Binding and photoreactivity of psoralen linked to triple helix-forming oligonucleotides

Triple helix-forming oligonucleotides conjugated to a psoralen (psoTFO) have been designed to bind to three distinct purine-rich sequences within the human interstitial collagenase (MMP1) gene. Gel mobility shift assays indicate that these psoTFO bind to and photoreact with model target DNA sequences following ultraviolet A (UVA) irradiation. The dissociation constants for binding of the psoTFO to their targets range from 0.3 to 4 microM. Psoralen monoadducts with the purine-rich target strand and interstrand crosslinks are efficiently formed on targets containing either 5'-ApT-3' or 5'-TpA-3' sequences adjacent to the TFO binding sequence. The dependence of adduct formation on UVA dose has provided quantitative estimates of the overall rate constants for psoralen monoadduct and crosslink formation in the presence of a TFO. When psoralen is tethered to a TFO, the rate of monoadduct formation exceeds that of crosslinking for all sequences studied. This contrasts with the relatively low rate of monoadduct formation that has been reported for free psoralens, suggesting that the bound TFO facilitates the initial photochemistry that generates monoadducts, but does not significantly affect interstrand crosslink formation. psoTFO and UVA treatment inhibit DNA cleavage by a restriction endonuclease when the psoralen covalently reacts directly at the endonuclease site. The particular TFO studied do not completely inhibit endonuclease activity when they are noncovalently bound or when the covalent psoralen adduct does not coincide with the endonuclease site. Our findings confirm that TFO are capable of directing psoralen photoadducts to specific DNA targets and suggest that TFO can significantly modulate psoralen photoreactivity and DNA-protein interactions.     

One-electron photooxidation and site-selective strand cleavage at 5-methylcytosine in DNA by sensitization with 2-methyl-1,4-naphthoquinone-tethered oligonucleotides

Photosensitized one-electron oxidation was applied to discriminate a specific base site of 5-methylcytosine (mC) generated in DNA possessing a partial sequence of naturally occurring p53 gene, using a sensitizing 2-methyl-1,4-naphthoquinone (NQ) chromophore tethered to an interior of oligodeoxynucleotide (ODN) strands. Photoirradiation and subsequent hot piperidine treatment of the duplex consisting of mC-containing DNA and NQ-tethered complementary ODN led to oxidative strand cleavage selectively at the mC site, when the NQ chromophore was arranged so as to be in close contact with the target mC. The target mC is most likely to be one-electron oxidized into the radical cation intermediate by the sensitization of NQ. The resulting mC radical cation may undergo rapid deprotonation and subsequent addition of molecular oxygen, thereby leading to its degradation followed by strand cleavage at the target mC site. In contrast to mC-containing ODN, ODN analogs with replacement of normal cytosine, thymine, adenine, or guanine at the mC site underwent less amount of such an oxidative strand cleavage at the target base site, presumably due to occurrence of charge transfer and charge recombination processes between the base radical cation and the NQ radical anion. Furthermore, well designed incorporation of the NQ chromophore into an interior of ODN could suppress a competitive strand cleavage at consecutive guanines, which occurred as a result of positive charge transfer. Thus, photosensitization by an NQ-tethered ODN led to one-electron oxidative strand cleavage exclusively at the target mC site, providing a convenient method of discriminating mC in naturally occurring DNA such as human p53 gene as a positive band on a sequencing gel.     

A new family of sequence-specific DNA-cleaving agents directed by triple-helical structures: benzopyridoindole-EDTA conjugates

Sequence-specific DNA recognition can be achieved by oligonucleotides that bind to the major groove of oligopyrimidine x oligopurine sequences. These intermolecular structures could be used to modulate gene expression and to create new tools for molecular biology. Here we report the synthesis and biochemical characterization of triple helix-specific DNA cleaving reagents. It is based on the previously reported triplex-specific ligands, benzo[e]pyridoindole (BePI) and benzo[g]pyridoindole (BgPI), covalently attached to ethylenediaminotetraacetic acid (EDTA). In the presence of iron, a reducing agent and molecular oxygen, BgPI-EDTA x FeII but not BePI-EDTA x FeII induced a double-stranded cut in a plasmid DNA at the single site where a triplex-forming oligonucleotide binds. At single nucleotide resolution, it was found that upon triplex formation BePI-EDTA x FeII led to cleavage of the pyrimidine strand and protection of the purine strand. BgPI-EDTA x FeII cleaved both strands with similar efficiency. The difference in cleavage efficiency between the two conjugates was rationalized by the location of the EDTA x FeII moiety with respect to the grooves of DNA (major groove: BePI-EDTA x FeII, minor groove: BgPI-EDTA x FeII). This work paves the way to the development of a new class of triple helix directed DNA cleaving reagents. Such molecules will be of interest for sequence-specific DNA cleavage and for investigating triple-helical structures, such as H-DNA, which could play an important role in the control of gene expression in vivo.     

Oxidation of DNA Hairpins by Oxoruthenium(IV): Effects of Sterics and Secondary Structure

The effects of steric hindrance on the oxidation of DNA by polypyridyl oxoruthenium(IV) complexes have been investigated. The complexes oxidize DNA by activation either of the 1' ribose C-H bond or by oxo transfer to the guanine nucleobase. A method is presented for determining the relative rates of activation of individual sites from the dependence of the extent of cleavage on the oxidant concentration. This analysis shows that hybridization of the labeled strand to its complement attenuates the rate of oxidation of guanine more effectively than the rate of sugar oxidation. Accordingly, higher ratios of guanine/sugar oxidation are observed in single strands. Among the individual guanine residues, however, the relative reactivities are not altered by hybridization; a similar result is obtained for sugar oxidation. This result implies that sequence-dependent chemical reactivity is partly responsible for the different extents of cleavage observed within the sequence. The ability of hybridization to protect guanine from oxidation is also apparent in hairpin studies, where the stem guanines are much less reactive than the loop guanines, and altered sugar conformations in the loop lead to modulated reactivity. Finally, a set of sterically differentiated complexes shows greater steric effects for oxidation of guanine compared to oxidation of sugar, as expected from the relative rates of the single strand and duplexes.     

Probing the solvent accessibility and electron density of adenine: oxidation of 7-deazaadenine in bent DNA and purine doublets

The effect of DNA bending on nucleobase electron transfer was investigated by studying the oxidation of double-stranded sequences containing seven repeats of the known bent sequence d(GGCA(1)A(2)A(3)A(4)A(5)A(6)C) where 7-deazaadenine (zA) was substituted at the A(3) position. Native gel electrophoresis was used to show that the sequence remained bent upon substitution of zA, which provides for oxidation of the sequence by Ru(bpy)(3)(3+) (bpy = 2,2'-bipyridine). The Ru(III) oxidant was generated by photolysis of Ru(bpy)(3)(2+) in the presence of ferricyanide, and the oxidation was visualized by high-resolution gel electrophoresis of the radiolabeled DNA sequence following base treatment. Cleavage of the DNA strand at the guanine residues and at the zA residues was observed. Comparison of the oxidation of zA in bent DNA versus the normal B form showed that hybridization of the B form sequence to its Watson-Crick complement produced a reduction in cleavage by a factor of 5.19 +/- 0.46 while hybridization of the bent sequence only reduced cleavage by a factor of 1.58 +/- 0.23. This result implies that the zA in the double-stranded, bent sequence is much more solvent-exposed than in normal B-form DNA. When the zA occurred in a B-form 5'-zA-G doublet, the reactivity was 6.63 +/- 0.10 times higher for the zA compared to the G. This implies an even greater effect of a 3'-guanine on the oxidation potential of zA than in the well-known 5'-GG doublet.     

Guanine-specific DNA oxidation photosensitized by the tetraphenylporphyrin phosphorus(V) complex via singlet oxygen generation and electron transfer

The photosensitized DNA damage caused by dihydroxoP(V)tetraphenylporphyrin (P(V)TPP), a cationic water-soluble porphyrin, was examined. The study of near-infrared emission measurements demonstrated the photosensitized singlet oxygen ((1)O(2)) generation by P(V)TPP (quantum yield: 0.28 in ethanol). The fluorescence quenching of P(V)TPP by DNA showed the electron transfer (ET) from nucleobases to photoexcited P(V)TPP. These results have shown that P(V)TPP has ability to damage DNA through dual mechanisms, (1)O(2) generation and ET. Under aerobic conditions, P(V)TPP photosensitized damage was more severe for single-stranded DNA compared to its double-stranded counterpart. Photoexcited P(V)TPP damaged every guanine residue in single-stranded DNA. HPLC measurements confirmed the formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodGuo), an oxidized product of 2'-deoxyguanosine, and showed that the yield of 8-oxodGuo in single-stranded DNA is larger than that in double-stranded DNA. The guanine-specific DNA damage and the enhancement in single-stranded DNA suggest that the (1)O(2) generation mainly contributes to the mechanism of DNA photodamage by P(V)TPP. Absorption spectrum measurements suggested the interaction between P(V)TPP and DNA. This interaction is expected to enhance the (1)O(2)-mediated DNA damage since the lifetime of (1)O(2) is very short. On the other hand, for double-stranded DNA, photosensitized damage at consecutive guanines was much less pronounced. Because the consecutive guanines act as a hole trap, this DNA-damaging pattern suggests the partial involvement of photoinduced ET. However, DNA damage by ET was not a main mechanism, possibly due to the reverse ET. In conclusion, P(V)TPP induces guanine specific photooxidation mainly via (1)O(2) generation. The interaction with DNA and the energy level of the photoexcited porphyrin may be advantageous for (1)O(2)-mediated DNA damage rather than ET mechanism.     

Photohydrolysis of methotrexate produces pteridine,which induces poly-G-specific DNA damage through photoinduced electron transfer

Methotrexate (MTX), an antineoplastic agent, demonstrates phototoxicity. The mechanism of damage to biomacromolecules induced by photoirradiated MTX was examined using 32P-labeled DNA fragments obtained from a human gene. Photoirradiated MTX caused DNA cleavage specifically at the underlined G in 5'-GG and 5'-GGG sequences in double-stranded DNA only when the DNA fragments were treated with piperidine, which suggests that DNA cleavage was caused by base modification with little or no strand breakage. With denatured single-stranded DNA the damage occurred at most guanine residues. The amount of formation of 8-hydroxy-2'-deoxyguanosine (8-oxodGuo), an oxidative product of 2'-deoxyguanosine, in double-stranded DNA exceeded that in single-stranded DNA. These results suggest that photoirradiated MTX participates in 8-oxodGuo formation at the underlined G in 5'-GG and 5'-GGG sequences in double-stranded DNA through electron transfer, and then 8-oxodGuo undergoes further oxidation into piperidine-labile products. Fluorescence measurement, high-pressure liquid chromatography and mass spectrometry have demonstrated that photoexcited MTX is hydrolyzed into 2,4-diamino-6-(hydroxymethyl)pteridine (DHP). DNA damage induced by DHP was observed in a similar manner as was the damage induced by MTX. The extent of DNA damage and the formation of 8-oxodGuo by DHP were much larger than those induced by MTX. The kinetic analysis, based on the time course of DNA oxidation by photoirradiated MTX, suggests that DNA damage is caused by photoexcited DHP rather than by photoexcited MTX. In conclusion, photoexcited MTX undergoes hydrolysis through intramolecular electron transfer, resulting in the formation of DHP, which exhibits a phototoxic effect caused by oxidation of biomacromolecules through photoinduced electron transfer.     

Stable oligonucleotide-directed triplex formation at target sites with CG interruptions: strong sequence-specific recognition by 2',4'-bridged nucleic-acid-containing 2-pyridones under physiological conditions

A sequence of double-stranded DNA (dsDNA) which can be recognized by a triplex-forming oligonucleotide (TFO) is limited to a homopurine-homopyrimidine sequence. To develop novel nucleoside analogues which recognize CG interruption in homopurine-homopyrimidine dsDNA, we synthesized a novel 2'-O,4'-C-methyleneribonucleic acid (2'-O,4'-C-methylene bridged nucleic acid; 2',4'-BNA) that bears the unnatural nucleobases, 2-pyridone (PB) or its 5-methyl congener (mPB); these analogues were introduced into pyrimidine TFOs using a DNA synthesizer. A TFO with a 2'-deoxy-beta-D-ribofuranosyl-2-pyridone (P) or 2',4'-BNA abasic monomer (HB) was also synthesized. The triplex-forming ability of various synthesized 15-mer TFOs and the corresponding homopurine-homopyrimidine dsDNA, which contained a single pyrimidine-purine (PyPu) interruption, was examined in UV melting experiments. It was found that PB and mPB in the TFOs successfully recognized CG interruption under physiological conditions (7 mM sodium phosphate, 140 mM KCl, 5 mM spermine, pH 7.0). Furthermore, triplex formation between the dsDNA target which contained three CG interruptions and the TFO with three PB units was also confirmed. Additional four-point 2',4'-BNA modifications of the TFO containing three PB units significantly enhanced its triplex-forming ability towards the dsDNA and had a Tm value of 43 degrees C under physiological conditions. These results indicate that a critical inherent problem of TFOs, namely, the sequence limitation of the dsDNA target, may be overcome to a large extent and this should promote antigene applications of TFOs in vitro and in vivo.     

Photosensitization of DNA damage by a new cationic pyropheophorbide derivative: sequence-specific formation of a frank scission

Pyropheophorbides are red-absorbing porphyrin-like photosensitizers that may interact with DNA either by intercalation or by external binding with self-stacking according to the value of the nucleotide to chromophore molar ratio (N/C). This article reports on the nature and sequence selectivity of the DNA damage photoinduced by a water-soluble chlorhydrate of aminopyropheophorbide. First, this pyropheophorbide is shown to induce on irradiation the cleavage of phiX174 DNA by both Type-I and -II mechanisms, suggested by scavengers and D2O effects. These conclusions are then improved by sequencing experiments performed on a 20-mer oligodeoxynucleotide (ODN) irradiated at wavelengths >345 nm in the presence of the dye, N/C varying from 2.5 to 0.5. Oxidation of all guanine residues to the same extent is observed after piperidine treatment on both single- and double-stranded ODN. Moreover, unexpectedly, a remarkable sequence-selective cleavage occurring at a 5'-CG-3' site is detected before alkali treatment. This frank break is clearly predominant for a low nucleotide to chromophore molar ratio, corresponding to a self-stacking of the dye along the DNA helix. The electrophoretic properties of the band suggest that this lesion results from a sugar oxidation, which leads via a base release to a ribonolactone residue. The proposal is supported by high-performance liquid chromatography-matrix-assisted laser desorption-ionization mass spectrometry experiments that also reveal other sequence-selective frank scissions of lower intensity at 5'-GC-3' or other 5'-CG-3' sites. This sequence selectivity is discussed with regard to the binding selectivity of cationic porphyrins.     

Mutagenesis Mediated by Triple Helix–Forming Oligonucleotides Conjugated to Psoralen: Effects of Linker Arm Length and Sequence Context

Targeted mutagenesis and gene knock-out can be mediated by triple helix-forming oligonucleotides (TFO) linked to mutagenic agents, such as psoralen. However, this strategy is limited by the availability of homopurine/ homopyrimidine stretches at or near the target site because such sequences are required for high-affinity triplex formation. To overcome this limitation, we have tested TFO conjugated to psoralen via linker arms of lengths varying from 2 to 86 bonds, thereby designed to deliver the psoralen at varying distances from the third strand binding site present at the 3'end of the supFG1 mutation reporter gene. Following triplex formation and UVA irradiation, mutations were detected using an SV40-based shuttle vector assay in human cells. The frequency and distribution of mutations depended on the length of the linker arm. Precise targeting was observed only for linker arms of length 2 and 6, which also yielded the highest mutation frequencies (3 and 14%, respectively). Psoralen–TFO with longer tethers yielded mutations at multiple sites, with the maximum distance from the triplex site limited by the linker length but with the distribution within that range influenced by the propensity for psoralen intercalation at A:T base-pair-rich sites. Thus, gene modification can be extended beyond the site of third strand binding but with a decrease in the precision of the targeting.     

Formation and stability of a Janus-Wedge type of DNA triplex

A new type of DNA targeting with the formation of a Janus-Wedge (J-W) triple helix is described. The "wedge" residue (W) attached to a PNA backbone is designed to insert itself into double-stranded DNA and base pair with both Watson-Crick faces. To study the stability of such an assembly, we have examined the formation of the J-W triplex with dC8 - T8 target sequence. The use of this target sequence permits the study of this new helix form without competing Watson-Crick interactions between the two target residues. Studies indicate that the W strand binds to both target strands, with defined polarity and a stability (-15.2 kcal/mol) that is roughly the sum of the two independent duplex interactions.     

Development of bridged nucleic acid analogues for antigene technology

In the last decade, increased efforts have been directed toward the development of oligonucleotide-based technologies for genome analyses, diagnostics, or therapeutics. Among them, an antigene strategy is one promising technology to regulate gene expression in living cells. Stable triplex formation between the triplex-forming oligonucleotide (TFO) and the target double-stranded DNA (dsDNA) is fundamental to the antigene strategy. However, there are two major drawbacks in triplex formation by a natural TFO: low stability of the triplex and limitations of the target DNA sequence. To overcome these problems, we have developed various bridged nucleic acids (BNAs), and found that the 2',4'-BNA modification of oligonucleotides strongly promotes parallel motif triplex formation under physiological conditions. Some nucleobase analogues to extend the target DNA sequence were designed, synthesized, and introduced into the 2',4'-BNA structure. The obtained 2',4'-BNA derivatives with unnatural nucleobases effectively recognized a pyrimidine-purine interruption in the target dsDNA. Some other examples of nucleic acid analogues for stable triplex formation and extension of the target DNA sequence are also summarized.     

Model transition states for methane diazonium ion methylation of guanine runs in oligomeric DNA

The DNA reaction pattern of the methane diazonium ion, which is the reactive intermediate formed from several carcinogenic methylating agents, was examined at N7 and O(6) sites in guanine runs occurring in oligonucleotides and model oligonucleotides. Density functional B3LYP/6-31G*, and SCF 3-21G and STO-3G energies of model transition states were calculated in the gas phase and in the CPCM reaction field. For nucleotides containing two, three, and four stacked guanines with counterions in the gas phase, O(6) reactivity is greater than N7 reactivity. In the reaction field, N7 reactivity is 9.0 to 9.8 times greater than O(6) reactivity. For a double-stranded oligonucleotide containing two stacked guanines with counterions in the reaction field, the N7 and O(6) reactivities of the 3'-guanine are 3.9 times greater than the corresponding sites in the 5'-guanine. For double-stranded oligonucleotides with three or four stacked guanines and counterions, the reactivities of the interior guanines are higher than corresponding reactivities of guanines at the ends. These reaction patterns agree with most of the available experimental data. Activation energy decomposition analysis for gas-phase reactions in a double-stranded dinucleotide containing two stacked guanines with counterions indicates that selectivity at O(6) is almost entirely due to electrostatic forces. Selectivity at N7 also has a large electrostatic interaction. However, the orbital interaction also contributes significantly to the gas-phase selectivity, accounting for 32% of the total interaction energy difference between the 3'- and 5'-guanine reactions. In aqueous solution, the relative orbital contribution to N7 selectivity is likely to be larger.     

"Hot spots" associated with the photoinduced binding of cis-dichloro bis(1,10 phenanthroline)rhodium(III) chloride to HIV-1 and c-raf DNA

The octahedral rhodium complex, cis-dichloro bis(1,10 phenanthroline)rhodium(III) chloride (BISPHEN), is known to form covalent linkages with DNA involving the attachment of the metal to a base. In order to determine the sequence selectivity of this chemistry, solutions of the complex containing one of the double-stranded DNA plasmids, pBSSK.c-raf (eco) or pBSKS+.XE.LTR-F (a construct that contains sequences derived from the long terminal repeat [LTR] region of the human immunodeficiency virus) have been irradiated using UVA light. The DNA samples were denatured after irradiation, a primer was annealed to one of the strands, and a complementary strand was constructed using a polymerase enzyme. Polyacrylamide gel sequencing analysis was used to reveal stops created in the complementary strand caused by the polymerase encountering a metal-bound base. The data indicate that "hot spots" primarily occur at, or adjacent to, guanines (G), with a particularly strong preference for strings of G. In the latter case, the hottest spot is at the 5'G. These results are consistent with our previously postulated mechanism for the covalent binding chemistry which involves photooxidation of deoxyguanosine by the excited state of the metal complex as the primary photochemical step.     

Base oxidation at 5' site of GG sequence in double-stranded DNA induced by UVA in the presence of xanthone analogues: relationship between the DNA-damaging abilities of photosensitizers and their HOMO energies

UVA contributes to skin cancer by solar UV light. Photosensitizers are believed to play an important role in UVA carcinogenesis. We investigated the mechanism of DNA damage induced by photoexcited xanthone (XAN) analogues (XAN, thioxanthone [TXAN] and acridone [ACR]), exogenous photosensitizers, and the relationship between the DNA-damaging abilities and their highest occupied molecular orbital (HOMO) energies. DNA damage by these photosensitizers was examined using 32P-labeled DNA fragments obtained from the p53 tumor suppressor gene. Photoexcited XAN caused DNA cleavage specifically at 5'-G of the GG sequence in the double-stranded DNA only when the DNA fragments were treated with piperidine, suggesting that DNA cleavage is due to base modification with little or no strand breakage. With denatured single-stranded DNA, the extent of XAN-sensitized photodamage was decreased. An oxidative product of G, 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dGuo), was formed by photoexcited XAN, and the 8-oxo-dGuo formation was decreased in single-stranded DNA. TXAN and ACR induced DNA photodamage as did XAN, although the order of DNA-damaging ability was XAN > TXAN > ACR. These findings suggest that photoexcited XAN analogues induce nucleobase oxidation at 5'-G of GG sequence in double-stranded DNA through electron transfer. The HOMO energies of these photosensitizers, estimated from ab initio molecular orbital (MO) calculation, decreased in the following order: XAN > TXAN > ACR. Extents of DNA damage increased exponentially with the HOMO energies of XAN analogues. This study suggests that DNA-damaging abilities of photosensitizers can be estimated from their HOMO energies.     

Helix-forming properties of size-expanded DNA, an alternative four-base genetic form

We describe the chemical and biophysical characterization of a new four-base genetic system, in which all base pairs are larger than the natural pairs. A recent preliminary study showed that three sequences containing size-expanded DNA (xDNA) bases could form stable cooperative complexes. However, many of the standard and essential properties that natural DNA possesses were unexplored for this new class of helical assembly. We therefore undertook a study of several properties of this new genetic complex: strand stoichiometry, preferred strand polarity (i.e., parallel vs antiparallel), mismatch selectivity, base size selectivity, ionic strength dependence, fluorescence behavior, CD spectra, and sequence generality. Results showed that several sequences formed double-stranded helical complexes, and interestingly, a pyrimidine-rich strand of xDNA bases was shown to form a triple helical complex as well. A test of strand polarity showed a preference for antiparallel orientation, as does natural DNA. Mismatch and size selectivity were generally moderate to strong, with one exception. Ionic strength dependence varied by relatively small degrees from that of natural DNA, although a triple helical complex of xDNA showed more marked dependence. Spectral characteristics (fluorescence, CD) were found to be quite different than those of natural DNA, apparently because of large differences in the electronic character of the expanded pi-systems. Finally, several sequence contexts were found to form helices in a sequence-predictable manner. Two exceptions were noted and may be explained by competition from alternative folding structures and/or strong, single-stranded stacking. The viability of xDNA as an alternative genetic system and its possible biotechnological applications are discussed.     

Dissecting the strand folding orientation and formation of G-quadruplexes in single- and double-stranded nucleic acids by ligand-induced photocleavage footprinting

The widespread of G-quadruplex-forming sequences in genomic DNA and their role in regulating gene expression has made G-quadruplex structures attractive therapeutic targets against a variety of diseases, such as cancer. Information on the structure of G-quadruplexes is crucial for understanding their physiological roles and designing effective drugs against them. Resolving the structures of G-quadruplexes, however, remains a challenge especially for those in double-stranded DNA. In this work, we developed a photocleavage footprinting technique to determine the folding orientation of each individual G-tract in intramolecular G-quadruplex formed in both single- and double-stranded nucleic acids. Based on the differential photocleavage induced by a ligand tetrakis(2-trimethylaminoethylethanol) phthalocyaninato zinc tetraiodine (Zn-TTAPc) to the guanines between the two terminal G-quartets in a G-quadruplex, this method identifies the guanines hosted in each terminal G-quartets to reveal G-tract orientation. The method is extremely intuitive, straightforward, and requires little expertise. Besides, it also detects G-quadruplex formation in long single- and double-stranded nucleic acids.