Spatial Structure of a DNA Duplex d(CGTTTATT)p-Net:d(AATAAACG) with an Unusual Localization of a Covalently Bound Netropsin (Net) Analog According to Two-Dimensional NMR Spectroscopy

Two-dimensional ¹H NMR (NOESY, COSY) spectroscopy was used to study the spatial structure of a DNA complex CGTTTATTp-Net:AATAAACG with a netropsin analog bound at the terminal 3-phosphate group in aqueous solution. The positions of the proton NMR signals of the duplex are compared with those for the unmodified duplex and the free ligand. A mean conformation of the duplex is constructed by the molecular mechanics technique using the obtained NMR limitations on the interproton distances. The data obtained indicate that the aromatic pyrrole rings of the netropsin analog are involved in a stacking interaction with the terminal AT base pair of the duplex; this is generally not typical of ordinary minor-groove netropsin type ligands.     

Guanine of the third strand of C.G*G triplex serves as an effective hole trap

We have examined the structural and electronic effects of the one-electron oxidation of the C.GG triplex, where G is located in a quite different environment from the G of duplex DNA. Upon photoirradiation of an external photosensitizer (riboflavin) with the C.GG triplex, oxidative DNA cleavage occurred exclusively at guanine repeat sequences in the third strand of triple helix DNA. Hole transport through the C.GG triplex also occurred, resulting in selective cleavage at G in the third strand. Thus, the hole generated in the duplex can migrate to GGG in the third strand and is trapped exclusively at Gs in the third strand. These experimental results, together with molecular orbital calculations, suggest that the origin of the selective strand cleavage can be explained as follows: (i) guanine repeat sequences in the third strand are more easily oxidized than in duplex DNA and (ii) in their radical cation states, G of the third strand rapidly deprotonates and reacts with oxygen and/or water, leading to strand cleavage. These results indicate that the oxidative damage preferentially occurred at Gs of the third strand owing to thermodynamic and kinetic features of the one-electron oxidation of the C.GG triplex.     

459—The effect of netropsin on the electrochemical oxidation of DNA at a graphite electrode

The interaction of netropsin with calf thymus, Bacillus cereus and Micrococcus luteus DNAs and with the RNA of phage f2 was studied by means of differential pulse voltammetry at a paraffin-wax-impregnated spectroscopic graphite electrode. It was found that the oxidation voltammetric peaks of double-helical calf thymus and Bacillus cereus DNAs were lowered when netropsin was added to the DNA solution. The peak corresponding to electro-oxidation of adenine residues was lowered more than that corresponding to electro-oxidation of guanine residues. Under the same experimental conditions the oxidation peaks of double-helical Micrococcus luteus DNA, double-helical RNA and thermally denatured samples of all DNAs used were almost uninfluenced by the addition of netropsin. The results observed were explained by (i) decreased flexibility of the segments to which netropsin was bound, and (ii) the specific binding of netropsin to the segments of double-helical DNA rich in adenine thymine pairs.     

DNA mediated charge transport: characterization of a DNA radical localized at an artificial nucleic acid base

DNA assemblies containing 4-methylindole incorporated as an artificial base provide a chemically well-defined system in which to explore the oxidative charge transport process in DNA. Using this artificial base, we have combined transient absorption and EPR spectroscopies as well as biochemical methods to test experimentally current mechanisms for DNA charge transport. The 4-methylindole radical cation intermediate has been identified using both EPR and transient absorption spectroscopies in oxidative flash-quench studies using a dipyridophenazine complex of ruthenium as the intercalating oxidant. The 4-methylindole radical cation intermediate is particularly amenable to study given its strong absorptivity at 600 nm and EPR signal measured at 77 K with g = 2.0065. Both transient absorption and EPR spectroscopies show that the 4-methylindole is well incorporated in the duplex; the data also indicate no evidence of guanine radicals, given the low oxidation potential of 4-methylindole relative to the nucleic acid bases. Biochemical studies further support the irreversible oxidation of the indole moiety and allow the determination of yields of irreversible product formation. The construction of these assemblies containing 4-methylindole as an artificial base is also applied in examining long-range charge transport mediated by the DNA base pair stack as a function of intervening distance and sequence. The rate of formation of the indole radical cation is >/=10(7) s(-)(1) for different assemblies with the ruthenium positioned 17-37 A away from the methylindole and with intervening A-T base pairs primarily composing the bridge. In these assemblies, methylindole radical formation at a distance is essentially coincident with quenching of the ruthenium excited state to form the Ru(III) oxidant; charge transport is not rate limiting over this distance regime. The measurements here of rates of radical cation formation establish that a model of G-hopping and AT-tunneling is not sufficient to account for DNA charge transport. Instead, these data are viewed mechanistically as charge transport through the DNA duplex primarily through hopping among well stacked domains of the helix defined by DNA sequence and dynamics.     

Rational design of a DNA wire possessing an extremely high hole transport ability

DNA is a promising conductive biopolymer. However, there are problems that need to be solved to realize real DNA wires. These include the low efficiency of hole transport and the serious oxidative damage that can occur during hole transport. We have demonstrated a protocol for the design of a DNA wire that can effectively mediate hole transport that is not adversely affected by oxidation during hole transport through the DNA duplex. We have synthesized a stable and effective DNA wire by incorporating a designer nucleobase, benzodeazaadenine derivatives, which have lower oxidation potentials and wider stacking areas but are not decomposed during hole transport.     

Selective one-electron oxidation of duplex DNA oligomers: reaction at thymines

The one-electron oxidation of duplex DNA generates a nucleobase radical cation (electron "hole") that migrates long distances by a hopping mechanism. The radical cation reacts irreversibly with H2O or O2 to form oxidation products (damaged bases). In normal DNA (containing the four common DNA bases), reaction occurs most frequently at guanine. However, in DNA duplexes that do not contain guanine (i.e., those comprised exclusively of A/T base pairs), we discovered that reaction occurs primarily at thymine and gives products resulting from oxidation of the T-C5 methyl group and from addition to its C5-C6 double bond. This surprising result shows that it is the relative reactivity, not the stability, of a nucleobase radical cation that determines the nature of the products formed from oxidation of DNA. A mechanism for reaction is proposed whereby a thymine radical cation may either lose a proton from its methyl group or H2O/O2 may add across its double bond. In the latter case, addition may initiate a tandem reaction that converts both thymines of a TT step to oxidation products.     

Examining the Effects of Netropsin on the Curvature of DNA A-Tracts Using Electrophoresis

A-tracts are sequences of repeated adenine bases that, under the proper conditions, are capable of mediating DNA curvature. A-tracts occur naturally in the regulatory regions of many organisms, yet their biological functions are not fully understood. Orienting multiple A-tracts together constructively or destructively in a phase has the potential to create different shapes in the DNA helix axis. One means of detecting these molecular shape differences is from altered DNA mobilities measured using electrophoresis. The small molecule netropsin binds the minor groove of DNA, particularly at AT-rich sequences including A-tracts. Here, we systematically test the hypothesis that netropsin binding eliminates the curvature of A-tracts by measuring the electrophoretic mobilities of seven 98-base pair DNA samples containing different numbers and arrangements of centrally located A-tracts under varying conditions with netropsin. We find that netropsin binding eliminates the mobility difference between the DNA fragments with different A-tract arrangements in a concentration-dependent manner. This work provides evidence for the straightening of A-tracts upon netropsin binding and illustrates an artificial approach to re-sculpt DNA shape.     

Effects of the photooxidant on DNA-mediated charge transport

A direct comparison of DNA charge transport (CT) with different photooxidants has been made. Photooxidants tested include the two metallointercalators, Rh(phi)(2)(bpy')(3+) and Ru(phen)(bpy')(dppz)(2+), and three organic intercalators, ethidium (Et), thionine (Th), and anthraquinone (AQ). CT has been examined through a DNA duplex containing an A(6)-tract intervening between two 5'-CGGC-3' sites with each of the photooxidants covalently tethered to one end of the DNA duplex. CT is assayed both through determination of the yield of oxidative guanine damage and, in derivative DNA assemblies, by analysis of the yield of a faster oxidative trapping reaction, ring opening of N(2)-cyclopropylguanine (d(CP)G) within the DNA duplex. We find clear differences in oxidative damage ratios at the distal versus proximal 5'-CGGC-3' sites depending upon the photooxidant employed. Importantly, nondenaturing gel electrophoresis data demonstrate the absence of any DNA aggregation by the DNA-bound intercalators. Hence, differences seen with assemblies containing various photooxidants cannot be attributed to differential aggregation. Comparisons in assemblies using different photooxidants thus reveal characteristics of the photooxidant as well as characteristics of the DNA assembly. In the series examined, the lowest distal/proximal DNA damage ratios are obtained with Ru and AQ, while, for both Rh and Et, high distal/proximal damage ratios are found. The oxidative damage yields vary in the order Ru > AQ > Rh > Et, and photooxidants that produce higher distal/proximal damage ratios have lower yields. While no oxidative DNA damage is detected using thionine as a photooxidant, oxidation is evident using the faster cyclopropylguanosine trap; here, a complex distance dependence is found. Differences observed among photooxidants as well as the complex distance dependence are attributed to differences in rates of back electron transfer (BET). Such differences are important to consider in developing mechanistic models for DNA CT.     

One-electron oxidation of DNA oligomers that lack guanine: reaction and strand cleavage at remote thymines by long-distance radical cation hopping

The anthraquinone (AQ) photosensitized one-electron oxidation of DNA introduces a radical cation (electron "hole") that migrates through the duplex by hopping. The radical cation normally is trapped irreversibly by reaction at guanine. We constructed AQ-linked DNA oligomers composed exclusively of A/T base pairs. Their irradiation led to reaction and strand cleavage primarily at thymines. Long-distance radical cation hopping to distant thymines was demonstrated by the distance dependence of the process and by experiments with DNA oligomers that contain a single remote GG step. The reaction of the radical cation at thymine was shown to involve its 5-methyl group by the replacement of selected thymines with uracils. These findings show that the reactivity of radical cations in DNA cannot be explained simply by exclusive reliance on the relative oxidation potential of the nucleobases. Instead, the site of reaction is determined in accord with the Curtin-Hammett principle for reactive species in rapid equilibrium.     

Possible cause of G-C-->C-G transversion mutation by guanine oxidation product, imidazolone

BACKGROUND: The genome is constantly assaulted by oxidation reactions which are likely to be associated with oxygen metabolism, and oxidative lesions are generated by many types of oxidants. Such genotoxin-induced alterations in the genomic message have been implicated in aging and in several pathophysiological processes, particularly those associated with cancer. The guanine base (G) in genomic DNA is highly susceptible to oxidative stress due to having the lowest oxidation potential. Therefore, G-C-->T-A and G-C-->C-G transversion mutations frequently occur under oxidative conditions. One typical lesion of G is 8-oxo-7,8-dihydro-guanine (8-oxoG), which can pair with A. This pairing may cause G-C-->T-A transversion mutations. Although the number of G-C-->C-G transversions is rather high under specific oxidation conditions such as riboflavin photosensitization, the molecular basis of G-C-->C-G transversions is not known. RESULTS: To determine which oxidative products are responsible for G-C-->C-G transversion mutations, we photooxidized 5'-d(AAAAAAGGAAAAAA)/5'-d(TTTTTTCCTTTTTT) using either riboflavin or anthraquinone (AQ) carboxylate under UV irradiation. Prolonged low-temperature (4 degrees C) enzymatic digestion of photoirradiated sample indicated that under both conditions the amount of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) initially increased with decreasing amounts of 2'-deoxyguanosine (dG), then decreased with the formation of 2-amino-5-[(2-deoxy-beta-D-erythro-pentofuranosyl)amino]-4H-imidazol-4-one (dIz), suggesting that nascent 8-oxoG was further oxidized to 2,5-diamino-4H-imidazol-4-one (Iz) in duplex DNA. Photoirradiation of an AQ-linked oligomer with a complementary strand containing 8-oxoG indicated that 8-oxoG residues were oxidized to Iz. These results indicate that Iz is formed from 8-oxoG through long-range hole migration. Primer extension experiments using a template containing Iz demonstrated that only dGTP is specifically incorporated opposite Iz suggesting that specific Iz-G base pairs are formed. The 'reverse' approach consisting of DNA polymerization using dIzTP showed that dIzTP is incorporated opposite G, further confirming the formation of a Iz-G base pair. CONCLUSIONS: HPLC product analysis demonstrated that Iz is a key oxidation product of G through 8-oxoG in DNA photosensitized with riboflavin or anthraquinone. Photoreaction of AQ-linked oligomer confirmed that Iz is formed from 8-oxoG through long-range hole migration. Two sets of primer extension experiments demonstrated that Iz can specifically pair with G in vitro. Specific Iz-G base pair formation can explain the G-C-->C-G transversion mutations that appear under oxidative conditions.     

One-electron oxidation of DNA: the effect of replacement of cytosine with 5-methylcytosine on long-distance radical cation transport and reaction

One-electron oxidation of duplex DNA generates a radical cation that migrates through the nucleobases until it is trapped by an irreversible reaction with water or oxygen. The trapping site is often a GG step, because this site has a relatively low ionization potential and this causes the radical cation to pause there momentarily. Modifications to guanine that lower its ionization potential convert it to a better trap for the radical cation. One such modification is the formation of the Watson-Crick base pair with cytosine, which is reported to very significantly decrease its ionization potential. Methylation of cytosine to form 5-methylcytosine (5-MeC) is a naturally occurring reaction in genomic DNA that may be associated with regions of enhanced oxidative damage. The G.5-MeC base pair is reported to be more rapidly oxidized than normal G.C base pairs. We examined the oxidation of DNA oligomers that were substituted in part with 5-MeC. Irradiation of a covalently linked anthraquinone group injects a radical cation into the DNA and results in strand cleavage after piperidine treatment. For the sequences examined, substitution of 5-MeC for C has no measurable effect on the reactions. Cytosine methylation is not a general cause of enhanced oxidative damage in DNA.     

Anthraquinone Photonucleases: A Surprising Role for Chloride in the Sequence-Neutral Cleavage of DNA and the Footprinting of Minor Groove-Bound Ligands

Irradiation of water-soluble anthraquinone (AQ) reagents in the presence of chloride ions results in the spontaneous, sequence-neutral cleavage of DNA. Mechanistic studies indicate that cleavage is initiated by chlorine atoms, produced by charge transfer interaction between chloride anion and AQ triplet states. High-resolution gel electrophoresis suggests that cleavage arises from abstraction of a hydrogen atom from C-4′ of deoxyribose units. The targeting of this hydrogen, which is located in the minor groove of duplex DNA, can be effectively blocked by netropsin and, to a lesser degree, berenil, leading to photofootprinting of these minor groove-binding drugs.     

Photooxidation of nucleic acids on metal oxides: physico-chemical and astrobiological perspectives

Photocatalytic oxidation of nucleic acid components on aqueous metal oxides (TiO(2), α-FeOOH, and α-Fe(2)O(3)) has been studied. The oxidation of purine nucleotides results in the formation of the purine radical cations and sugar-phosphate radicals, whereas the oxidation of pyrimidine nucleotides other than thymine results in the oxidation of only the sugar-phosphate. The oxidation of the thymine (and to a far less extent for the 5-methylcytosine) derivatives results in deprotonation from the methyl group of the base. Some single stranded (ss) oligoribonucleotides and wild-type ss RNA were oxidized at purine sites. In contrast, double stranded (ds) oligoribonucleotides and DNA were not oxidized. These results account for observations suggesting that cellular ds DNA is not damaged by exposure to photoirradiated TiO(2) nanoparticles inserted into the cell, whereas ss RNA is extensively damaged. The astrobiological import of our observations is that the rapid degradation of monomer nucleotides make them poor targets as biosignatures, whereas duplex DNA is a better target as it is resilient to oxidative diagenesis. Another import of our studies is that ds DNA (as opposed to ss RNA) appears to be optimized to withstand oxidative stress both due to the advantageous polymer morphology and the subtle details of its radical chemistry. This peculiarity may account for the preference for DNA over RNA as a "molecule of life" provided that metal oxides served as the template for synthesis of polynucleotides, as suggested by Orgel and others.     

Long-range oxidative damage to DNA: protection of guanines by a nonspecifically bound disulfide

One-electron oxidation of DNA generates a base radical cation ("hole") that migrates through the duplex and causes damage at guanines. Unrepaired damage may lead to mutations. It has been suggested that "sacrificial guanines" in intron regions of DNA might serve to protect genes from damage. We have investigated the ability of a noncovalently bound sacrificial reagent to protect DNA from damage. Irradiation of an anthraquinone (AQ)-linked DNA duplex injects a radical cation into the DNA that causes reactions at GG steps close to and farther from the AQ. Bis[2-(3-(aminopropyl)amino)ethyl]disulfide, an analogue of spermine, binds to duplex DNA. Irradiation of the AQ-linked DNA in the presence of this disulfide suppresses the reaction at both GG steps and protects the DNA from damage. It is suggested that evolutionary pressure for the preservation of genomic integrity would yield disulfide-containing compounds optimized to bind to DNA and neutralize base radical cations.     

Interaction between antitumor drugs and a double-stranded oligonucleotide studied by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry was used to investigate the complex formation between a double-stranded oligonucleotide and various antitumor drugs belonging to two categories: intercalators (ethidium bromide, amsacrine and ascididemin) and minor groove binders (Hoechst 33258, netropsin, distamycin A, berenil and DAPI). The goal of this study was to determine whether the relative intensities in the mass spectra reflect the relative abundances of the species in the solution phase. The full-scan mass spectra suggest non-specific binding for the intercalators and specific binding for the minor groove binders. The preferential stoichiometries adopted by each minor groove binder were determined by studying the influence of the drug concentration on the spectra. We obtained 2:1 > 1:1 for distamycin, 1:1 > 2:1 for Hoechst 33258 and DAPI and only the 1 : 1 complex for netropsin and berenil. These features reflect their known behavior in solution. The compared tandem mass spectra of the 1 : 1 complexes with Hoechst 33258 and netropsin, when correlated with published crystallographic data, suggest the possibility of inferring some structural information. The relative binding affinities of the drug for the considered duplex were deduced with two by two competition experiments, assuming that the relative intensities reflect the composition of the solution phase. The obtained affinity scale is netropsin > distamycin A > DAPI > Hoechst 33258 > berenil. These examples show some of the potential uses of mass spectrometry as a useful tool for the characterization of specific drug binding to DNA, and possibly a rapid drug screening method requiring small amounts of materials.     

Oxidation of guanine in double-stranded DNA by [Ru(bpy)2dppz]Cl2 in cationic reverse micelles

DNA oxidation has been investigated in the medium of cationic reverse micelles (RMs). The oxidative chemistry is photochemically initiated using the DNA intercalator bis(bipyridine)dipyridophenazine ruthenium(II) chloride ([Ru(bpy)2dppz]Cl2) bound to duplex DNA in the RMs. High-resolution polyacrylamide gel electrophoresis (PAGE) is used to reveal and quantify guanine (G) oxidation products, including 8-oxo-7,8-dihydroguanine (8OG). In buffer solution, the addition of the oxidative quenchers potassium ferricyanide or pentaamminechlorocobalt(III) dichloride leads to an increase in the amount of piperidine-labile G oxidation products generated via one-electron oxidation. In RMs, however, the yield of oxidatively generated damage is attenuated. With or without ferricyanide quencher in the RMs, the yield of oxidatively generated products is approximately the same. Inclusion of the cationic quencher [CoCl(NH3)5]2+ in the RMs increases the amount of oxidation products generated but not to the extent that it does in buffer solution. Under anaerobic conditions, all of the samples in RMs, with or without added oxidative quenchers, show decreased levels of piperidine-labile oxidation products, suggesting that the primary oxidant in RMs is singlet oxygen. G oxidation is enhanced in D2O and deuterated heptane and is diminished in the presence of sodium azide in RMs, also supporting 1O2 as the main G oxidant in RMs. Isotopic labeling experiments show that the oxygen atom in 8OG produced in RMs is not from water. The observed change in the G oxidation mechanism from a one-electron process in buffer to mostly 1O2 in RMs illustrates the importance of both DNA structure and DNA environment on the chemistry of G oxidation.     

NETROPSIN: INTERACTION WITH ULTRAVIOLET IRRADIATED DNA

Abstract—Ultraviolet irradiation of double-stranded DNA reduces the circular dichroism (i < 300 nm) induced when the basic peptide antibiotic netropsin (Nt) is added to DNA subsequent to thc irradiation compared to the CD induced by the same concentrations of Nt added to unirradiated DNA. Nt is known to bind to A T base pairs in duplex DNA but will not bind to single-stranded DNA. The reduction in the maximum induced CD observed with saturating concentrations of Nt is a linear function of the concentration of pyrimidine dimers which. along with other dinucleotide photoproducts. form short disrupted regions in duplex DNA. The decrease in the CD of Nt bound to irradiated DNA could be due to elimination of potential Nt sites in the vicinity of a dimer. reduction in the average magnitude of the CD of Nt bound near a dimer or various combinations of these effects. In addition there is a reduction in the average binding constant for Nt bound to irradiated DNA compared to unirradiated DNA suggesting that formation of dinucleotide photoproducts either tends to preferentially eliminate the tighter binding sites or that tighter sites are converted to weaker ones. A simple model suggests that no more than one-third to one-half of the pyrimidine dimcrs formed in DNA completely eliminate a Nt site.     

Interaction of distamycin-oligopeptides with the self-complementary (d-CACAAGCTTGTG)2 duplex in solution

The complex formation of the DNA groove binding drugs netropsin, distamycin-3 and distamycin-5 with the self-complementary duplex (d-CACAAGCTTGTG)₂ has been investigated using CD titration measurements. Employing a general curve fitting program for data analysis, binding constants of complex formation and stoichiometry numbers were evaluated for the two distamycin-type oligopeptides. The binding model assumes simultaneous occurrence of two kinds of complexes characterized by (1:1) - and (1:2) -stoichiometry (duplex:ligand). The binding constants obtained for the (1:1)-complexes for distamycin-3 as well as for distamycin-5 are in full agreement with those calculated for the duplex sequence by means of the single-base specific binding constants of the methylpyrole carboxamide group of Gursky et al. [33]. Obtained binding results are explained by a possible interaction mechanism of distamycin with the particular dodecamer duplex in solution.     

Synthesis and study of naphthacenedione (TQ) as a photosensitizer for one-electron oxidation of DNA

[reaction: see text] Photosensitizers are useful for the study of one-electron oxidation of DNA. Most such photosensitizers absorb light in the UV spectral region. We report the synthesis and investigation of a 5,12-naphthacenedione (TQ) derivative as a DNA photosensitizer. Irradiation of a TQ-linked duplex with visible light results in reaction of the DNA that is characteristic of one-electron oxidation. The results from TQ sensitization are identical, within experimental error, with that of a well-studied anthraquinone derivative.     

Dynamic behavior of DNA base pairs containing 8-oxoguanine

The process by which DNA repair enzymes recognize and selectively excise damaged bases in duplex DNA is fundamental to our mechanistic understanding of these critical biological reactions. 8-Oxoguanine (8-oxoG) is the most common form of oxidative DNA damage; unrepaired, this lesion generates a G:C-->T:A mutation. Central to the recognition and repair of DNA damage is base extrusion, a process in which the damaged base lesion or, in some cases, its partner disengages from the helix and is bound to the enzyme's active site where base excision takes place. The conformation adopted by 8-oxoG in duplex DNA is affected by the base positioned opposite this lesion; conformational changes may also take place when the damaged base binds to its cognate repair enzyme. We performed unrestrained molecular dynamics simulations for several 13-mer DNA duplexes. Oligomers containing G:C and 8oxoG:C pairs adopted Watson-Crick geometries in stable B-form duplexes; 8oxoG showed increased local and global flexibility and a reduced barrier to base extrusion. Duplexes containing the G:A mismatch showed much larger structural fluctuations and failed to adopt a well-defined structure. For the 8oxoG:A mismatch that is recognized by the DNA glycosylase MutY, the damaged nucleoside underwent spontaneous and reproducible anti-->syn transitions. The syn conformation is thermodynamically preferred. Steric hindrance and unfavorable electrostatics associated with the 8oxoG O8 atom in the anti conformation were the major driving forces for this transition. Transition events follow two qualitatively different pathways. The overall anti-->syn transition rate and relative probability of the two transition paths were dependent on local sequence context. These simulations indicate that both the dynamic and equilibrium behavior of the duplex change as a result of oxidation; these differences may provide valuable new insight into the selective action of enzymes on damaged DNA.