Mechanistic studies on the base-catalyzed transformation of neocarzinostatin chromophore: roles of bulged DNA

Nucleic acid bulges have been implicated in a number of biological processes and are specific cleavage targets for the enediyne antitumor antibiotic neocarzinostatin chromophore (NCS-chrom) in a base-catalyzed, radical-mediated reaction. Studies designed to elucidate the detailed mechanism of the base-catalyzed activation of NCS-chrom and to evaluate the roles of bulged DNA in its activation are described. They show that nucleobases in the DNA bulge are not required to form an effective bulge pocket but enhance the binding of the wedge-shaped activated drug molecule. Analysis of solvent deuterium isotope effects on NCS-chrom degradation and DNA cleavage efficiency experiments suggests that the spirolactone biradical 6 is a relatively stable species and that intramolecular quenching of the C2 radical of 6 to form the biologically active cyclospirolactone radical 7a occurs first (pathway a in Scheme 2), leaving the C6 radical to abstract the hydrogen atom from the DNA deoxyribose and to form the cyclospirolactone 8. Binding of the activated drug at the bulge site is required, but not sufficient, for efficient 8 formation, whereas cleavage of bulged DNA is not essential. Efficient generation of 8, but inefficient DNA damage generation, comes mainly from the likely high off-rate of 7a binding. The finding that thymidine 5'-carboxylic acid-ended oligonucleotide fragment can be formed in the reaction suggests that the process of DNA cleavage is rather slow and that sequential oxidations of the target 5'-carbon are possible. Study of the effect of solvent (methanol) concentration on NCS-chrom degradation indicates that bulged DNA acts to assist the intramolecular quenching of the radical at C2 by C8' ' of the naphthoate moiety by excluding solvent from the binding pocket, thus preventing the formation of spirolactones 9, and by blocking radical polymerization. Because in the absence or near absence of solvent methanol 8 formation does not reach even 10% that formed in the presence of bulged DNA, it is possible that the DNA bulge also induces a conformational change in the drug to promote the intramolecular reaction.     

Product analyses in DNA strand scission by antitumor antibiotic elsamicin A.

Elsamicin A is an antitumor antibiotic with fascinating chemical structure and a good candidate for pharmaceutical development. Molecular mechanism of DNA backbone cleavage mediated by Fe(II)-elsamicin A has been examined. Product analysis using DNA sequencing gels and HPLC reveals the production of damaged DNA fragments bearing 3'-/5'-phosphate and 3'-phosphoglycolate termini associated with formation of free base. In addition, hydrazine-trapping experiments indicate that C-4' hydroxylated abasic sites are formed concomitant with DNA degradation by Fe(II)-elsamicin A. The results lead to the conclusion that the hydroxyl radical formed in Fe(II)-elsamicin A plus dithiothreitol system oxidizes the deoxyribose moiety via hydrogen abstraction predominantly at the C-4' carbon of the deoxyribose backbone and ultimately produces strand breakage of DNA.     

ESR studies on DNA cleavage induced by enediyne C-1027 chromophore

C-1027 belongs to the family of chromoprotein antitumor antibiotics, which contain a carrier apoprotein and a highly unstable enediyne chromophore. The enediyne spontaneously aromatizes to generate p-benzyne biradical, and subsequently abstracts hydrogens from the DNA sugar backbone, resulting in cleavage of the double strand. Using spin-trapping methods, we obtained direct proof of radical intermediates during an DNA cleavage, and found intriguing difference in behavior between the trapping agents 2-methyl-2-nitrosopropane (MNP) and 5,5-dimethyl-1-pyrroline N-oxide (DMPO): MNP added to the sugar radicals of the DNA, whereas DMPO directly trapped a phenyl radical or p-benzyne biradical derived from the C-1027 chromophore.     

Chromium(VI)-mediated DNA damage: oxidative pathways resulting in the formation of DNA breaks and abasic sites

Inside cells chromium(VI) is activated to its ultimate carcinogenic form by reducing agents including glutathione (GSH) and ascorbate (AsA). The precise mechanism by which DNA damaging species are formed is unclear. In earlier in vitro work with isolated DNA we have shown that chromium(VI) in combination with GSH or AsA is able to induce similar numbers of single strand breaks and apurinic/apyrimidinic sites (AP-sites). Moreover, the formation of both lesions followed a similar temporal pattern. It is conceivable that the two forms of DNA damage arise from a common precursor lesion (e.g. hydrogen abstraction at C4' of the DNA sugar moiety) with a partitioning along two pathways, one yielding an AP-site, the other a single strand break (SSB) and a base propenal. The present study is intended to test this hypothesis by analysing whether oxidation products of deoxyribose can be formed in the presence of chromium(VI) and GSH or AsA. It was found that mixtures of chromium(VI) and GSH or AsA were able to oxidise 2-deoxyribose to yield malondialdehyde, which was detected by reaction with thiobarbituric acid. The characteristic pink chromogen, which forms upon reaction with thiobarbituric acid, was also observed with calf thymus DNA as the substrate. In both experimental systems the addition of catalase prevented the formation of deoxyribose breakdown products. Hydroxyl radicals did not seem to be important for the generation of DNA damage as the characteristic modified DNA bases could not be detected by using gas chromatography-mass spectrometry. These results lead us to conclude that the formation of SSB during the reductive conversion of chromium(VI) proceeds primarily via hydrogen abstraction from C4'. The observation that Fenton chemistry is not involved in these processes is intriguing and necessitates further research into the ways in which chromium can activate molecular oxygen to form DNA damaging species.     

Formation of modified cleavage termini from the reaction of chromium(V) with DNA

Reaction of a 25 bp oligonucleotide with the high valent chromium complex, bis(2-ethyl-2-hydroxybutyrato)oxochromate(V) (Cr(V)-EHBA) produced both Frank- and alkali-labile strand breaks that were sequence-neutral. Frank strand break formation was found to be O2-dependent while formation of alkali-labile strand breaks were O2-independent. Reaction of Cr(V)-EHBA with the 5'-32P-labeled oligomer under oxygenated conditions formed the modified 3'-terminus, 3'-phosphoglycolate, as well as the 3'-phosphate terminus. Formation of the 3'-phosphoglycolate termini, and the O2 dependence of the reactions were consistent with a mechanism involving abstraction of the C4' hydrogen atom from the deoxyribose moiety of DNA. Identical reactions using the 3'-32P-labeled oligomer yielded only 5'-phosphate termini as assigned by co-migration with Maxam-Gilbert markers. Analogous cleavage profiles and modified termini were observed for the reaction of Cr(V)-EHBA and DNA in the presence of hydrogen peroxide. With the addition of hydrogen peroxide, the DNA cleavage reactions were O2-independent and the level of DNA cleavage was enhanced over that observed with Cr(V)-EHBA alone. These findings suggest an oxidation mechanism whereby a reductive intermediate of the carcinogen chromate, Cr(V), can cause DNA damage that mimics oxygen radical DNA damaging pathways.     

Atomic Scissors: A New Method of Tracking the 5-Bromo-2′-Deoxyuridine-Labeled DNA In Situ

A new method of the light microscopy detection of BrdU-labeled DNA in situ is described. It is based on the oxidative attack at the deoxyribose moiety by copper(I) in the presence of oxygen, which leads to the abstraction of hydrogen atom from deoxyribose culminating in the elimination of the nucleobase, scission of the nucleic-acid strand and formation of frequent gaps. The gaps allow the reaction of the antibodies with the commonly used markers of replication (e.g. 5-bromo-2′-deoxyuridine), which are otherwise masked. The method developed makes it possible to detect nuclear and mitochondrial DNA replication efficiently. In most cases, it does not inhibit effective protein detections and in addition enables simultaneous localization of newly-synthesized RNA. The alternative presently-used methods result in protein denaturation and/or extensive DNA cleavage followed by the DNA-bound proteins peeling off.     

Oxidative damage of DNA induced by the cytochrome C and hydrogen peroxide system

To elaborate the peroxidase activity of cytochrome c in the generation of free radicals from H2O2, the mechanism of DNA cleavage mediated by the cytochrome c/H2O2 system was investigated. When plasmid DNA was incubated with cytochrome c and H2O2, the cleavage of DNA was proportional to the cytochrome c and H2O2 concentrations.Radical scavengers, such as azide, mannitol, and ethanol, significantly inhibited the cytochrome c/H2O2 system-mediated DNA cleavage. These results indicated that free radicals might participate in the DNA cleavage by the cytochrome c and H2O2 system. Incubation of cytochrome c with H2O2 resulted in a time-dependent release of iron ions from the cytochrome c molecule. During the incubation of deoxyribose with cytochrome c and H2O2, the damage to deoxyribose increased in a time-dependent manner, suggesting that the released iron ions may participate in a Fenton-like reaction to produce dOH radicals that may cause the DNA cleavage. Evidence that the iron-specific chelator, desferoxamine (DFX), prevented the DNA cleavage induced by the cytochrome c/H2O2 system supports this mechanism. Thus we suggest that DNA cleavage is mediated via the generation of dOH by a combination of the peroxidase reaction of cytochrome c and the Fenton-like reaction of free iron ions released from oxidatively damaged cytochrome c in the cytochrome c/H2O2 system.     

DNA cleaving modes in minor groove of DNA helix by esperamicin and calicheamicin antitumor antibiotics.

This study examines and compares DNA cleavage modes by several esperamicin derivatives and calicheamicin. We found that the deoxyfucose-anthranilate moiety is a key factor to determine their DNA cutting modes. Probably, the bulky moiety hinders the abstraction of hydrogen atom from deoxyribose by the C-1 carbon radical of phenylene diradical. On the basis of the experimental results, detailed DNA cleaving modes in DNA minor groove by esperamicin and calicheamicin have been discussed.     

Quantum chemical studies for oxidation of morpholine by Cytochrome P450

Since morpholine oxidation has recently been shown to involve Cytochrome P450, the study on its mechanism at molecular level using quantum chemical calculations for the model of cytochrome active site is reported here. The reaction pathway is investigated for two electronic states, the doublet and the quartet, by means of density functional theory. The results show that morpholine hydroxylation occurs through hydrogen atom abstraction and rebound mechanism. However, in the low spin state, the reaction is concerted and hydrogen atom abstraction yields directly ferric-hydroxy morpholine complex without a distinct rebound step while in quartet state the reaction is stepwise. The presence of nitrogen in a morpholine heterocycle is postulated to greatly facilitate hydrogen abstraction. The hydroxylated product undergoes intramolecular hydrogen atom transfer from hydroxy group to nitrogen, leading to the cleavage of the C-N bond and the formation of 2-(2-aminoethoxy) acetaldehyde. The cleavage of the C-N bond is indicated as the rate-determining step for the studied reaction. The assistance of explicit water molecule is shown to lower the energy barrier for the C-N bond cleavage in enzymatic environment whereas solvent effects mimicked by COSMO solvent model have minor influence on relative energies along the pathway.     

A density functional theory study of the decomposition mechanism of nitroglycerin

The detailed decomposition mechanism of nitroglycerin (NG) in the gas phase was studied by examining reaction pathways using density functional theory (DFT) and canonical variational transition state theory combined with a small-curvature tunneling correction (CVT/SCT). The mechanism of NG autocatalytic decomposition was investigated at the B3LYP/6-31G(d,p) level of theory. Five possible decomposition pathways involving NG were identified and the rate constants for the pathways at temperatures ranging from 200 to 1000 K were calculated using CVT/SCT. There was found to be a lower energy barrier to the β-H abstraction reaction than to the α-H abstraction reaction during the initial step in the autocatalytic decomposition of NG. The decomposition pathways for CHOCOCHONO₂ (a product obtained following the abstraction of three H atoms from NG by NO₂) include O–NO₂ cleavage or isomer production, meaning that the autocatalytic decomposition of NG has two reaction pathways, both of which are exothermic. The rate constants for these two reaction pathways are greater than the rate constants for the three pathways corresponding to unimolecular NG decomposition. The overall process of NG decomposition can be divided into two stages based on the NO₂ concentration, which affects the decomposition products and reactions. In the first stage, the reaction pathway corresponding to O–NO₂ cleavage is the main pathway, but the rates of the two autocatalytic decomposition pathways increase with increasing NO₂ concentration. However, when a threshold NO₂ concentration is reached, the NG decomposition process enters its second stage, with the two pathways for NG autocatalytic decomposition becoming the main and secondary reaction pathways.     

Studies on the mechanism of aromatase and other cytochrome P450 mediated deformylation reactions

Aromatase is a microsomal cytochrome P450 that converts androgens to estrogens by three sequential oxidations. The isolation of the 19-hydroxy and 19-oxo androgens suggests that the first two oxidations occur at the C₁₉ carbon. However, the mechanism of the third oxidation, which results in C₁₀---C₁₉ bond cleavage, has not been determined. Two proposed mechanisms which remain viable involve either initial 1β-hydrogen atom abstraction or addition of the ferric peroxy anion from aromatase to the C₁₉ aldehyde. Semiempirical molecular orbital calculations (AM1) were used to study potential reaction mechanisms initiated by initial 1β-hydrogen atom abstraction. Initially, the energetics of carbon---carbon bond cleavage of the keto and enol forms of C1-radicals were studied and were found to be energetically similar. A mechanism was proposed in which the 19-oxo intermediate is subject to initial nucleophilic attack by the protein. The geometry of the A-ring in the androgens is between that for the 1-radicals and estrogen, suggesting that some transition state stabilization for the homolytic cleavage reaction can occur.

More recently, studies on liver microsomal cytochrome P450 mediated deformylation of xenobiotic aldehydes supports mechanisms involving an alkyl peroxy intermediate formed by addition of the ferric peroxy anion from aromatase to the C₁₉ aldehyde. Although this intermediate could proceed through several different concerted or non-concerted pathways, one non-concerted pathway involves the heterolytic cleavage of the dioxygen bond resulting in an active oxygenating species (iron-oxene) and a diol. The diol could then undergo hydrogen atom abstraction followed by homolytic carbon---carbon bond cleavage as in the mechanisms modeled previously. When this cleavage was modeled for seven aldehydes, a good correlation with reported experimental aldehyde turnover numbers was obtained. However, when dialkoxy derivatives of the aldehydes are subject to microsomal metabolism, the rates of carbon---carbon cleavage products do not approach the rates of deformylation of the aldehyde analog.     

DNA strand scission by activated bleomycin group antibiotics

The bleomycins (BLMs) are a structurally related group of antitumor antibiotics used clinically for the treatment of certain malignancies. The mechanism of action of the BLM is believed to involve DNA strand scission, a process that requires O2 and an appropriate metal ion; the therapeutically relevant metal is probably iron or copper. DNA strand scission by activated Fe X BLM involves oxygenation C-4' of deoxyribose and leads to two sets of products. One set results from scission of the C-3'--C-4' bond of deoxyribose, with concomitant cleavage of the DNA chain. The other set of products consists of free bases and an alkali-labile lesion, the latter of which leads to DNA chain cleavage on subsequent treatment with base. The structures of all of these degradation products have now been established by direct comparison with authentic synthetic samples. Also studied was the activation of BLM with (mono)oxygen surrogates such as iodosobenzene. The chemistry of the activated BLM so formed was remarkably similar to that of activated cytochrome P-450 and structurally related metalloporphyrins, which suggests a mechanistic analogy between the two. Remarkably, both Fe X BLM and Cu X BLM were also shown to be activated by NADPH cytochrome P-450 reductase in a transformation that was dependent on metal ion, O2 and NADPH.     

4-Hydroxyphenylpyruvate dioxygenase: a hybrid density functional study of the catalytic reaction mechanism

Density functional calculations using the B3LYP functional has been used to study the reaction mechanism of 4-hydroxyphenylpyruvate dioxygenase. The first part of the catalytic reaction, dioxygen activation, is found to have the same mechanism as in alpha-ketoglutarate-dependent enzymes; the ternary enzyme-substrate-dioxygen complex is first decarboxylated to the iron(II)-peracid intermediate, followed by heterolytic cleavage of the O-O bond yielding an iron(IV)-oxo species. This highly reactive intermediate attacks the aromatic ring at the C1 position and forms a radical sigma complex, which can either form an arene oxide or undergo a C1-C2 side-chain migration. The arene oxide is found to have no catalytic relevance. The side-chain migration is a two-step process; the carbon-carbon bond cleavage first affords a biradical intermediate, followed by a decay of this species forming the new C-C bond. The ketone intermediate formed by a 1,2 shift of an acetic acid group rearomatizes either at the active site of the enzyme or in solution. The hypothetical oxidation of the aromatic ring at the C2 position was also studied to shed light on the 4-HPPD product specificity. In addition, the benzylic hydroxylation reaction, catalyzed by 4-hydroxymandelate synthase, was also studied. The results are in good agreement with the experimental findings.     

Efficient, Mg(2+)-dependent photochemical DNA cleavage by the antitumor quinobenzoxazine (S)-A-62176

The quinobenzoxazines, a group of structural analogues of the antibacterial fluoroquinolones, are topoisomerase II inhibitors that have demonstrated promising anticancer activity in mice. It has been proposed that the quinobenzoxazines form a 2:2 drug-Mg(2+) self-assembly complex on DNA. The quinobenzoxazine (S)-A-62176 is photochemically unstable and undergoes a DNA-accelerated photochemical reaction to afford a highly fluorescent photoproduct. Here we report that the irradiation of both supercoiled DNA and DNA oligonucleotides in the presence of (S)-A-62176 results in photochemical cleavage of the DNA. The (S)-A-62176-mediated DNA photocleavage reaction requires Mg(2+). Photochemical cleavage of supercoiled DNA by (S)-A-62176 is much more efficient that the DNA photocleavage reactions of the fluoroquinolones norfloxacin, ciprofloxacin, and enoxacin. The photocleavage of supercoiled DNA by (S)-A-62176 is unaffected by the presence of SOD, catalase, or other reactive oxygen scavengers, but is inhibited by deoxygenation. The photochemical cleavage of supercoiled DNA is also inhibited by 1 mM KI. Photochemical cleavage of DNA oligonucleotides by (S)-A-62176 occurs most extensively at DNA sites bound by drug, as determined by DNase I footprinting, and especially at certain G and T residues. The nature of the DNA photoproducts, and inhibition studies, indicate that the photocleavage reaction occurs by a free radical mechanism initiated by abstraction of the 4'- and 1'-hydrogens from the DNA minor groove. These results lend further support for the proposed DNA binding model for the quinobenzoxazine 2:2 drug-Mg(2+) complex and serve to define the position of this complex on the minor groove of DNA.     

Photolytic cleavage of DNA by nitrobenzamido ligands linked to 9-aminoacridines gives DNA polymerase substrates in a wavelength-dependent reaction.

A series of reagents containing 3- or 4-nitrobenzamido ligands tethered to 9-aminoacridine via variable-length linkers have been prepared and their properties as photochemical DNA cleavers (photonucleases) examined. When irradiated with approximately 300-nm light, where the nitrobenzamido ligand can absorb, they cleave DNA in an oxygen-independent reaction presumably involving oxygen transfer from the nitro group to the deoxyribose units of the DNA backbone (Nielsen et al., 1988b). This reaction is pH independent and only slightly affected by the linker length, and the DNA fragments are not substrates for DNA polymerase. When approximately 420-nm light is used, were only the 9-aminoacridinyl ligands absorb, the DNA cleavage is also oxygen-independent but pH dependent, requires DNA saturation with the reagent (base pair:reagent less than or equal to 2), and is most efficient with the longer linkers. The cleavage is specific for guanine residues and results in 5'-phosphate termini and heterogeneous (more than four products) 3'-termini. One of the products is presumably 3'-hydroxy since DNA photocleaved with nitrobenzamido acridine reagents and 420-nm radiation are substrates for DNA polymerase in a nick translation assay as well as for the Klenow fragment. An electron-transfer mechanism is suggested.     

Atypical abasic sites generated by neocarzinostatin at sequence-specific cytidylate residues in oligodeoxynucleotides

Neocarzinostatin chromophore produces alkali-labile, abasic sites at cytidylate residues in AGC sequences in oligonucleotides in their duplex form. Glutathione is the preferred thiol activator of the drug in the formation of these lesions. The phosphodiester linkages on each side of the abasic site are intact, but when treated with alkali, breaks are formed with phosphate moieties at each end. Similar properties are exhibited by the abasic lesions produced at the purine residue to which the C in AGC is base-paired on the complementary strand. The abasic sites at C residues differ from those produced by acid-induced depurination in the much greater lability of the phosphodiester linkages on both sides of the deoxyribose, in the inability of NaBH4 to prevent alkali-induced cleavage, and in the relative resistance to apurinic/apyrimidinic endonucleases. The importance of DNA microstructure in determining attack site specificity in abasic site formation at C residues is shown not only by the requirement for the sequence AGC but also by the findings that substitution of G by I 5' to the C decreases the attack at C, whereas placement of an I opposite the C markedly enhances the reaction. Quantitation of the abstraction of 3H into the drug from C residues in AGC specifically labeled in the deoxyribose at C-5' or C-1',2' suggests that, in contrast to the attack at C-5' in the induction of direct strand breaks at T residues, abasic site formation at C residues may involve attack at C-1'. Each type of lesion may exist on the complementary strands of the same DNA molecule, forming a double-stranded lesion.     

Reaction of methylated urates with 1,1-diphenyl-2-picrylhydrazyl

The kinetics of the reaction between the stable free radical 1,1-diphenyl-2-picrylhydrazyl (DPPH) and methylated urates was studied. Urates that had methyl groups on the 1,3,9, or on the 1 and 3 or 1 and 9 nitrogens reacted with DPPH 15 to 77% faster than uric acid. Urates substituted with methyl groups on the 7 nitrogen or on both the 3 and 9 nitrogens reacted with DPPH at rates that were less than 0.1 that of uric acid. 3,7,9-Trimethyluric acid and 1,3,7,9-tetramethyluric acid reacted with DPPH at barely detectable rates. DPPH reacted with uric acid, the monomethylated urates, and some of the dimethylated urates in a ratio of 2:1. DPPH reacted with other dimethylated and trimethylated urates in a ratio of 1:1. Semiempirical MNDO calculations indicate that the most stable radical of uric acid is formed by hydrogen abstraction from the 3, 7 or 9 position. The most stable species resulting from loss of a second hydrogen lack hydrogens at the 3 and 7 positions or the 7 and 9 positions. For maximum reactivity with DPPH, methylated uric acid derivatives must have a hydrogen at nitrogen 7 and one of the hydrogens at either the 3 or 9 position.     

31P NMR characterization of terminal phosphates induced on DNA by the artificial nuclease ''Mn-TMPyP/KHSO5'' in comparison with DNases I and II.

Phosphorus-31 NMR has been applied to the characterization of terminal phosphates on fragments of calf thymus DNA induced by three different nuclease systems: DNase I, DNase II and the artificial nuclease 'Mn-TMPyP/KHSO5'. In this last case, the oxidative damage to deoxyribose leads to two monophosphates esters (at the 3' and 5' ends) on both sides of the cleavage site. This method constitutes a promising approach to visualise the phosphate termini generated in DNA or RNA cleavage by cytotoxic drugs or chemical nucleases and provides a novel insight into the molecular aspects of their mechanism of action.     

Activation of neocarzinostatin chromophore and formation of nascent DNA damage do not require molecular oxygen.

Thiol-activated neocarzinostatin chromophore abstracts tritium from the 5', but not from the 1' or 2' positions of deoxyribose in DNA and incorporates it into a stable, non-exchangeable form. The abstracted tritium remains covalently associated with the chromophore or its degradation product after treatment with acid or alkali, respectively. Drug activation and the consequent hydrogen abstraction reaction, presumably generating a carbon-centered radical at C-5', do not require molecular oxygen but have a dose-dependent relation with thiol. Under aerobic conditions, where base release and DNA strand breaks with nucleoside 5'-aldehyde at the 5'-ends are produced, hydrogen abstraction from C-5' parallels these parameters of DNA damage. It is possible to formulate a reaction scheme in which the carbon- centered radical at C-5' is an intermediate in the formation of the various DNA damage products found under both aerobic and anaerobic conditions.