Oxygen independent DNA interstrand cross-link formation by a nucleotide radical

A 5-(2'-Deoxyuridinyl)methyl radical (1) was independently generated from three photochemical precursors and is the first example of a DNA radical that forms interstrand cross-links. Oxygen labeling experiments support generation of 1 by all precursors. Interstrand cross-links are produced upon irradiation of DNA containing any of the precursors. Cross-linking occurs via reaction with the opposing 2'-deoxyadenosine and is independent of O(2). The independence of cross-link formation on O(2) is explained by kinetic analysis, which shows that the radical reacts reversibly with O(2). Examination of the effects of glutathione on cross-link formation under anaerobic conditions suggests that adoption of the syn-conformation by 1 is the rate-limiting step in the process. Interstrand cross-link formation is reversible in the presence of a good nucleophile. The stability of the interstrand cross-link suggests that the isolated molecule is a rearrangement product of that formed in solution. The rearrangement is a consequence of the isolation procedure but also occurs slowly in solution. Oxygen independent cross-link formation may be useful for the purposeful damage of DNA in hypoxic tumor cells, where O(2) is deficient.     

Near-UV induced interstrand cross-links in anthraquinone-DNA duplexes

Anthraquinone (AQ) has been extensively used as a photosensitizer to study charge transfer in DNA. Near-UV photolysis of AQ induces electron abstraction in oligonucleotides leading to AQ radical anions and base radical cations. In general, this reaction is followed by the transport of base radical cations to sites of low oxidation potential, that is, GG, and conversion of G radical cations to DNA breaks. Here, we show that AQ also produces interstrand cross-links in DNA duplexes. About half of the cross-links collapse to single strands in hot piperidine treatment. The structure of stable interstrand cross-links was deduced by MS, NMR, and sequence substitution. The cross-links consist of a covalent link between the methyl group of T on one strand with either C6 or C7 of AQ on the other strand. The formation of interstrand cross-links decreased in O2 compared to deoxygenated solutions. In the presence of O2, the yield of breaks at GG doublets was 10-fold greater than that of cross-links for end tethered AQ, while cross-links exceeded breaks for centrally located AQ. The formation of stable cross-links can be explained by initial charge transfer from T to excited AQ, deprotonation of T radical cations, and condensation of the latter species with AQ radicals. These studies reveal a novel pathway of damage in the photolysis of AQ-DNA duplexes.     

Radiosensitization by a modified nucleotide that produces DNA interstrand cross-links under hypoxic conditions

This paper describes the reactivity of a molecule that combines two desirable chemical processes into one molecule for the first time. Interstrand cross-links (ISCs) are an effective family of lesions produced by cytotoxic agents that target DNA. For instance, ISCs are the source of mitomycin C's cytotoxicity. Radiosensitizing agents are molecules that enhance DNA damage produced by ionizing radiation, especially under O2-deficient conditions. Phenyl selenide 1 is the first example of a modified nucleotide that can be incorporated in DNA by polymerases, which produces ISCs when DNA containing it is exposed to gamma-radiolysis under O2-deficient conditions. These experiments suggest that 1 could be useful as a novel type of radiosensitizing agent.     

THE EFFECT OF DARK COMPLEXING ON THE PHOTOSENSITIZED FORMATION OF 8-METHOXYPSORALEN CROSS-LINKS WITH DNA*

The near-UV dose at 365 nm required for the formation of 8-methoxypsoralen (8-MOP) cross-links with calf thymus DNA was found to be insensitive to the concentration ratio of nucleotides to 8-MOP over the range 100:1 to 5:1. The proposed explanation is that only the dark-complexed 8-MOP contributes to the photosensitized formation of monoadducts and cross-links. A kinetics analysis indicates that the fluence required for cross-linking should be inversely proportional to the square root of the fraction of dark-complexed 8-MOP per nucleotide (the binding ratio), a quantity that is insensitive to the ratio of nucleotides to 8-MOP. These findings predict a small dependence of photosensitivity on the total 8-MOP concentration in cellular systems in which cross-links are the major lethal lesion.     

Protein binding has a large effect on radical mediated DNA damage

Oxidative DNA damage is important in aging and a variety of diseases. Significant advances have been made in our understanding of the chemistry of radical mediated DNA damage. These studies have been carried out on DNA in the absence of proteins. However, in cells DNA is typically bound by proteins such as in chromatin and transiently by proteins that regulate biochemical processes. How and whether protein binding affects DNA radical reactivity is not well understood. The effect of the DNA binding protein Hbb on the reactivity of the 5-(2'-deoxyuridinyl)methyl radical (1) and 5-(2'-deoxycytidinyl)methyl radical (2) was studied. Hbb bends DNA and disrupts base stacking at the sites of kinking. The reactivity of 1 and 2 are significantly affected when they are generated at the kinking site in the presence of Hbb. The increased conformational mobility of the radicals results in significantly higher yields of DNA interstrand cross-links. These studies provide the first specific data on how protein binding affects the reactivity of a DNA radical and bring us closer to understanding oxidative DNA damage in cells.     

Self-promoted DNA interstrand cross-link formation by an abasic site

The C4'-oxidized abasic site (C4-AP) is produced in DNA as a result of oxidative stress. A recent report suggests that this lesion forms interstrand cross-links. Using duplexes in which C4-AP is produced from a synthetic precursor, we show that the lesion produces interstrand cross-links in which both strands are in tact and cross-links in which the C4-AP containing strand is cleaved. The yields of these products are dependent upon the surrounding nucleotide sequence. When C4-AP is opposed by dA, cross-link formation occurs exclusively with an adjacent dA on the 5'-side. Moreover, formation of the lower molecular weight cross-link is promoted by an opposing adenine. When the opposing dA is replaced by dT, the activity of the adenine can be rescued by adding the free base. This is a rare example in which DNA promotes its own modification, an observation that is all the more important because of the biological significance of the product produced.     

Characterization of lysine-guanine cross-links upon one-electron oxidation of a guanine-containing oligonucleotide in the presence of a trilysine peptide

Formation of DNA-protein cross-links involving the initial formation of a guanine radical cation was investigated. For this purpose, riboflavin-mediated photosensitization of a TGT oligonucleotide in aerated aqueous solution in the presence of the KKK tripeptide was performed. We have shown that the nucleophilic addition of the epsilon-amino group of the central lysine residue of KKK to the C8 atom of either the guanine radical cation or its deprotonated form gives rise to the efficient formation of a Nepsilon-(guanin-8-yl)-lysine cross-link. Interestingly, the time course of formation of the above-mentioned cross-link was found to be not linear with the time of irradiation, and its formation rapidly reached a plateau. This is explained by secondary decomposition of the initially generated cross-link which could be further oxidized more efficiently than starting TGT oligonucleotide. One-electron oxidation of the initially generated cross-link was found to produce mainly two diastereomeric cross-links exhibiting a spiroimino-trilysine-dihydantoin structure as inferred from enzymatic digestion, CD, UV, NMR and mass spectrometry measurements. In addition, other minor cross-links, for which formation was favored at acidic pH, were assigned as lysine-guanine adducts in which the modified guanine base exhibits a guanidino-trilysine-iminohydantoin structure. A proposed mechanism for the formation of the different detected oligonucleotide-peptide cross-links is given. The high yield of formation of the detected cross-links strongly suggests that a DNA-protein cross-link involving a lysine residue linked to the C8 position of guanine could be generated in cellular systems if a lysine is located in the close vicinity of a guanine radical cation. KEYWORDS: oxidatively generated DNA damage, photosensitization, guanine radical cation, DNA-protein cross-links.     

Demonstration of an alternative mechanism for G-to-G cross-link formation

The cross-link dG-to-dG is an important product of DNA nitrosation. Its formation has commonly been attributed to nucleophilic substitution of N2 in a guaninediazonium ion by guanine, while recent studies suggest guanine addition to a cyanoamine derivative formed after dediazoniation, deprotonation, and pyrimidine ring-opening. The chemical viability of the latter mechanism is supported here by the experimental demonstration of rG-to-aG formation via rG addition to a synthetic cyanoamine derivative. Thus, all known products of nitrosative guanine deamination are consistent with the postulate of pyrimidine ring-opening. This postulated mechanism not only explains what is already known but also suggests that other products and other cross-links also might be formed in DNA deamination. The study suggests one possible new product: the structure isomer aG(N1)-to-rG(C2) of the classical G(N2)-to-G(C2) cross-link. While the formation of aG(N2)-to-rG(C2) has been established by chemical synthesis, the structure isomer aG(N1)-to-rG(C2) has been assigned tentatively based on its MS/MS spectrum and because this assignment is reasonable from a mechanistic perspective. Density functional calculations show preferences for the amide-iminol tautomer of the classical cross-link G(N2)-to-G(C2) and the amide-amide tautomer of G(N1)-to-G(C2). Moreover, the results suggest that both cross-links are of comparable thermodynamic stability, and that there are no a priori energetic or structural reasons that would prevent the formation of the structure isomer in the model reaction or in DNA.     

Visible light induced DNA-protein crosslinking in DNA-histone complex and sarcoma-180 chromatin in the presence of methylene blue

Formation of DNA-protein cross-links by the action of visible light in the presence of methylene blue was studied in calf thymus DNA-calf thymus histone complex and sarcoma-180 chromatin. The extent of cross-link formation decreases with a decrease in the histone to DNA ratio in the DNA-histone complex. In chromatin, it is at a maximum (93%) at a dye to DNA nucleotide ratio (D/P ratio) of 0.04 and is appreciable even at a very low dye concentration (75% at a D/P ratio of 0.0033). Sepharose 4B-CL column chromatography indicates that methylene blue acts as a mediator in the cross-linking process, but not as a linker in the DNA-protein cross-link. Dodecylsulphate-polyacrylamide gel electrophoresis patterns reveal that both histone and non-histone proteins are involved in cross-linking, but to a varied extent. Competition experiments with ethidium bromide demonstrated the necessity of intercalative binding of methylene blue in the formation of DNA--protein cross-links. Viscometric studies in 2 M NaCl indicate that the compact structure of chromatin is stabilized by cross-linking.     

DNA interstrand cross-link formation initiated by reaction between singlet oxygen and a modified nucleotide

DNA is the target of many anti-cancer therapies. These agents damage the biopolymer by oxidation or by alkylation. Interstrand DNA cross-links are believed to be the source of cytotoxicity of anti-tumor agents, such as mitomycin C, which alkylate the biopolymer. In contrast, deoxyguanosine oxidation is the result of reaction between DNA and singlet oxygen, which is the damaging species produced in photodynamic therapy. We have shown that, upon oxidation by singlet oxygen, an analogue of thymidine (2) rearranges to a methide, which forms DNA-DNA interstrand cross-links. This novel process suggests that 2 may be a useful adjuvant in photodynamic therapy.     

Structure of the nitrogen-centered radical formed during inactivation of E. coli ribonucleotide reductase by 2'-azido-2'-deoxyuridine-5'-diphosphate: trapping of the 3'-ketonucleotide

Ribonucleotide reductases (RNRs) catalyze the conversion of nucleotides to deoxynucleotides providing the monomeric precursors required for DNA replication and repair. The class I RNRs are composed of two homodimeric subunits: R1 and R2. R1 has the active site where nucleotide reduction occurs, and R2 contains the diiron tyrosyl radical (Y*) cofactor essential for radical initiation on R1. Mechanism-based inhibitors, such as 2'-azido-2'-deoxyuridine-5'-diphosphate (N(3)UDP), have provided much insight into the reduction mechanism. N(3)UDP is a stoichiometric inactivator that, upon interaction with RNR, results in loss of the Y* in R2 and formation of a nitrogen-centered radical (N*) covalently attached to C225 (R-S-N*-X) in the active site of R1. N(2) is lost prior to N* formation, and after its formation, stoichiometric amounts of 2-methylene-3-furanone, pyrophosphate, and uracil are also generated. On the basis of the hyperfine interactions associated with N*, it was proposed that N* is also covalently attached to the nucleotide through either the oxygen of the 3'-OH (R-S-N*-O-R') or the 3'-C (R-S-N*-C-OH). To distinguish between the proposed structures, the inactivation was carried out with 3'-[(17)O]-N(3)UDP and N* was examined by 9 and 140 GHz EPR spectroscopy. Broadening of the N* signal was detected and the spectrum simulated to obtain the [(17)O] hyperfine tensor. DFT calculations were employed to determine which structures are in best agreement with the simulated hyperfine tensor and our previous ESEEM data. The results are most consistent with the R-S-N*-C-OH structure and provide evidence for the trapping of a 3'-ketonucleotide in the reduction process.     

Cisplatin damage overrides the predefined rotational setting of positioned nucleosomes

Cisplatin and carboplatin are used successfully to treat various types of cancer. The drugs target the nucleosomes of cancer cells and form intrastrand DNA cross-links that are located in the major groove. We constructed two site-specifically modified nucleosomes containing defined intrastrand cis-{Pt(NH3)2}(2+) 1,3-d(GpTpG) cross-links. Histones from HeLa-S3 cancer cells were transferred onto synthetic DNA duplexes having nucleosome positioning sequences. The structures of these complexes were investigated by hydroxyl radical footprinting. Employing nucleosome positioning sequences allowed us to quantify the structural deviation induced by the cisplatin adduct. Our experiments demonstrate that a platinum cross-link locally overrides the rotational setting predefined in the nucleosome positioning sequence such that the lesion faces toward the histone core. Identical results were obtained for two DNA duplexes in which the sites of platination differed by approximately half a helical turn. Additionally, we determined that cisplatin unwinds nucleosomal DNA globally by approximately 24 degree. The intrastrand cis-{Pt(NH3)2}(2+) 1,3-d(GpTpG) cross-links are located in an area of the nucleosome that contains locally overwound DNA in undamaged reference nucleosomes. Because most nucleosome positions in vivo are defined by the intrinsic DNA sequence, the ability of cisplatin to influence the structure of these positioned nucleosomes may be of physiological relevance.     

Independent generation and reactivity of 2-deoxy-5-methyleneuridin-5-yl, a significant reactive intermediate produced from thymidine as a result of oxidative stress

2'-Deoxy-5-methyleneuridin-5-yl (1) is produced in a variety of DNA damage processes and is believed to result in the formation of lesions that are mutagenic and refractory to enzymatic repair. 2'-Deoxy-5-methyleneuridin-5-yl (1) was independently generated under anaerobic conditions via Norrish Type I photocleavage during Pyrex filtered photolysis of the benzyl ketone 7. The radical (1) exhibits behavior consistent with that of a resonance-stabilized radical. The KIE for hydrogen atom transfer from t-BuSH was found to be 7.3 +/- 1.7. Competition studies between radical recombination and hydrogen atom donors (2,5-dimethyltetrahydrofuran, kTrap = 46.1 +/- 15.4 M(-1) s(-1); propan-2-ol, kTrap = 13.6 +/- 3.5 M(-1) s(-1)) chosen to mimic the carbohydrate components of 2'-deoxyribonucleotides suggest that 2'-deoxy-5-methyleneuridin-5-yl (1) may be able to transfer damage from the nucleobase to the deoxyribose of an adjacent nucleotide in DNA under hypoxic conditions.     

The effects of secondary structure and O2 on the formation of direct strand breaks upon UV irradiation of 5-bromodeoxyuridine-containing oligonucleotides.

BACKGROUND: 5-Bromodeoxyuridine is a radiosensitizing agent that is currently being evaluated in clinical trials as an adjuvant in the treatment of a variety of cancers. gamma-Radiolysis and UV irradiation of oligonucleotides containing 5-bromodeoxyuridine result in the formation of direct strand breaks at the 5'-adjacent nucleotide by oxidation of the respective deoxyribose. We investigated the effects of DNA secondary structure and O2 on the induction of direct strand breaks in 5-bromodeoxyuridine-containing oligonucleotides. RESULTS: The efficiency of direct strand break formation in duplex DNA is dependent upon O2 and results in fragments containing 3'-phosphate and the labile 3'-ketodeoxyadenosine termini. The ratio of the 3'-termini is also dependent upon O2 and structure. Deuterium product isotope effects and tritium-transfer studies indicate that hydrogen-atom abstraction from the C1'- and C2'-positions occurs in an O2- and structure-dependent manner. CONCLUSIONS: The reaction mechanisms by which DNA containing 5-bromodeoxyuridine is sensitized to damage by UV irradiation are dependent upon whether the substrate is hybridized and upon the presence or absence of O2. Oxygen reduces the efficiency of direct strand break formation in duplex DNA, but does not affect the overall strand damage. It is proposed that the sigma radical abstracts hydrogen atoms from the C1'- and C2'-positions of the 5'-adjacent deoxyribose moiety, whereas the nucleobase peroxyl radical selectively abstracts the C1'-hydrogen atom from this site. This is the second example of DNA damage amplification by a nucleobase peroxyl radical, and might be indicative of a general reaction pattern for this family of reactive intermediates.     

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.     

Skin photosensitizing agents and the role of reactive oxygen species in photoaging.

In this paper, the role of reactive oxygen species in photoaging is presented. Many photosensitizing agents are known to generate reactive oxygen species (singlet oxygen (1O2), superoxide anion (O2.-) and .OH radicals). Although photoaging (dermatoheliosis) of human skin is caused by UVB and UVA radiation, the hypothesis tested here in the pathogenesis of photoaging of human skin is the free radical theory involving the generation of reactive oxygen species by UVA (320-400 nm) radiation and their damaging oxidative effects on cutaneous collagen and other model proteins. The UVA-generated reactive oxygen species cause cross-linking of proteins (e.g. collagen), oxidation of sulfydryl groups causing disulfide cross-links, oxidative inactivation of certain enzymes causing functional impairment of cells (fibroblasts, keratinocytes, melanocytes, Langerhans cells) and liberation of proteases, collagenase and elastase. The skin-damaging effects of UVA appear to result from type II, oxygen-mediated photodynamic reactions in which UVA or near-UV radiation in the presence of certain photosensitizing chromophores (e.g., riboflavin, porphyrins, nicotinamide adenine dinucleotide phosphate (NADPH), etc.) leads to the formation of reactive oxygen species (1O2, O2.-, .OH). Four specific observations are presented to illustrate the concept: (1) the production of 1O2 and O2.- by UVB, UVA and UVA plus photosensitizing agents (such as riboflavin, porphyrin and 3-carbethoxypsoralens) as a function of UV exposure dose, the sensitizer concentration and the pH of the irradiated solution; (2) the formation of protein cross-links in collagen, catalase and superoxide dismutase by 1O2 and O2.- (.OH) and the resulting denaturation of proteins and enzyme activities as a function of UVA exposure dose; (3) the protective role of selective quenchers of 1O2 and O2.- (e.g. alpha-tocopherol acetate, beta-carotene, sodium azide, ascorbic acid, etc.) against the photoinactivation of enzymes and the prevention of the protein cross-linking reaction; (4) the possible usefulness of certain antioxidants or quenchers that interact with the UVA-induced generation of reactive oxygen species in the amelioration of the process of photoaging.     

DNA damage induced via independent generation of the radical resulting from formal hydrogen atom abstraction from the C1′-position of a nucleotide

Background: Deoxyribonucleotide radicals resulting from formal C1′-hydrogen atom abstraction are important reactive intermediates in a variety of DNA-damage processes. The reactivity of these radicals can be affected by the agents that generate them and the environment in which they are produced. As an initial step in determining the factors that control the reactivity of these important radical species, we developed a mild method for their generation at a defined site within a biopolymer.Results: Irradiation of oligonucleotides containing a photolabile nucleotide produced C1'-DNA radicals. In the absence of potential reactants other than O₂, approximately 90% of the damage events involve formation of alkaline-labile lesions, with the remainder resulting in direct strand breaks. The ratio of alkaline-labile lesions to direct strand breaks (∼ 9:1) is independent of whether the radical is generated in single-stranded DNA or double-stranded DNA. Strand damage is almost completely quenched under anaerobic conditions in the presence of low thiol concentrations. Competition studies with 02 indicate that the trapping rate of C1′-DNA radicals by β-mercaptoethanol is ∼ 1.1 x 10⁷ M⁻¹s⁻¹Conclusions: The mild generation of the C1'-DNA radical in the absence of exogenous oxidants makes it possible to examine their intrinsic reactivity. In the absence of other reactants, the formation of direct strand breaks from C1′-radicals is, at most, a minor pathway. Competition studies between β-mercaptoethanol and 02 indicate that significantly higher thiol concentrations than those in vivo or some means of increasing the effective thiol concentration near DNA are needed for these reagents to prevent the formation of DNA lesions arising from the C1'-radical under aerobic conditions.     

FR900482 class of anti-tumor drugs cross-links oncoprotein HMG I/Y to DNA in vivo

BACKGROUND: Overexpression of the high-mobility group, HMG I/Y, family of chromatin oncoproteins has been implicated as a clinical diagnostic marker for both neoplastic cellular transformation and increased metastatic potential of several human cancers. These minor groove DNA-binding oncoproteins are thus an attractive target for anti-tumor chemotherapy. FR900482 represents a new class of anti-tumor agents that bind to the minor groove of DNA and exhibit greatly reduced host toxicity compared to the structurally related mitomycin C class of anti-tumor drugs. We report covalent cross-linking of DNA to HMG I/Y by FR900482 in vivo which represents the first example of a covalent DNA-drug-protein cross-link with a minor groove-binding oncoprotein and a potential novel mechanism through which these compounds exert their anti-tumor activity. RESULTS: Using a modified chromatin immunoprecipitation procedure, fragments of DNA that have been covalently cross-linked by FR900482 to HMG I/Y proteins in vivo were polymerase chain reaction-amplified, isolated and characterized. The nuclear samples from control cells were devoid of DNA fragments whereas the nuclear samples from cells treated with FR900482 contained DNA fragments which were cross-linked by the drug to the minor groove-binding HMG I/Y proteins in vivo. Additional control experiments established that the drug also cross-linked other non-oncogenic minor groove-binding proteins (HMG-1 and HMG-2) but did not cross-link major groove-binding proteins (Elf-1 and NFkappaB) in vivo. Our results are the first demonstration that FR900482 cross-links a number of minor groove-binding proteins in vivo and suggests that the cross-linking of the HMG I/Y oncoproteins may participate in the mode of efficacy as a chemotherapeutic agent. CONCLUSIONS: We have illustrated that the FR class of anti-tumor antibiotics, represented in this study by FR900482, is able to produce covalent cross-links between the HMG I/Y oncoproteins and DNA in vivo. The ability of this class of compounds to cross-link the HMG I/Y proteins in the minor groove of DNA represents the first demonstration of drug-induced cross-linking of a specific cancer-related protein to DNA in living cells. We have also demonstrated that FR900482 cross-links other minor groove-binding proteins (HMG-1 and HMG-2 in the present study) in vivo; however, since HMG I/Y is the only minor groove-binding oncoprotein presently known, it is possible that these non-histone chromatin proteins are among the important in vivo targets of this family of drugs. These compounds have already been assessed as representing a compelling clinical replacement for mitomycin C due to their greatly reduced host toxicity and superior DNA interstrand cross-linking efficacy. The capacity of FR900482 to cross-link the HMG I/Y oncoprotein with nuclear DNA in vivo potentially represents a significant elucidation of the anti-tumor efficacy of this family of anticancer agents.     

Long range 1,4 and 1,6-interstrand cross-links formed by a trinuclear platinum complex. Minor groove preassociation affects kinetics and mechanism of cross-link formation as well as adduct structure

Reported here is a comparison of the kinetics of the stepwise formation of 1,4- and 1,6-GG interstrand cross-links by the trinuclear platinum anticancer compound (15)N-[[trans-PtCl(NH(3))(2)](2)[mu-trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+), (1,0,1/t,t,t (1) or BBR3464). The reactions of (15)N-1 with the self-complementary 12-mer duplexes 5'-[d(ATATGTACATAT)(2)] (I) and 5'-[d(TATGTATACATA)(2)] (II) have been studied at 298 K, pH 5.3 by [(1)H,(15)N] HSQC 2D NMR spectroscopy. The kinetic profiles for the two reactions are similar. For both sequences initial electrostatic interactions with the DNA are observed for 1 and the monoaqua monochloro species (2) and changes in the chemical shifts of certain DNA (1)H resonances are consistent with binding of the central charged [PtN(4)] linker unit in the minor groove. The pseudo first-order rate constants for the aquation of 1 to 2 in the presence of duplex I (3.94 +/- 0.03 x 10(-5) s(-1)), or II(4.17 +/- 0.03 x 10(-5) s(-1)) are ca. 40% of the value obtained for aquation of 1 under similar conditions in the absence of DNA. Monofunctional binding to the guanine N7 of the duplex occurs with rate constants of 0.25 +/- 0.02 M(-1) s(-1) (I) and 0.34 +/- 0.02 M(-1) s(-1) (II), respectively. Closure to form the 1,4- or 1,6-interstrand cross-links (5) was treated as direct from 3 with similar rate constants of 4.21 +/- 0.06 x 10(-5) s(-1) (I) and 4.32 +/- 0.04 x 10(-5) s(-1) (II), respectively. Whereas there is only one predominant conformer of the 1,6 cross-link, evidence from both the (1)H and [(1)H,(15)N] NMR spectra show formation of two distinct conformers of the 1,4 cross-link, which are not interconvertible. Closure to give the major conformer occurs 2.5-fold faster than for the minor conformer. The differences are attributed to the initial preassociation of the central linker of 1 in the minor groove and subsequently during formation of both the monofunctional and bifunctional adducts. For duplex I, molecular models indicate two distinct pathways for the terminal [PtN(3)Cl] groups to approach and bind the guanine N7 in the major groove with the central linker anchored in the minor groove. To achieve platination of the guanine residues in duplex II the central linker remains in the minor groove but 1 must diffuse off the DNA for covalent binding to occur. Clear evidence for movement of the linker group is seen at the monofunctional binding step from changes of chemical shifts of certain CH(2) linker protons as well as the Pt-NH(3) and Pt-NH(2) groups. Consideration of the (1)H and (15)N shifts of peaks in the Pt-NH(2) region show that for both the 1,4 and 1,6 interstrand cross-links there is a gradual and irreversible transformation from an initially formed conformer(s) to product conformer(s) in which the amine protons of the two bound [PtN(3)] groups exist in a number of different environments. The behavior is similar to that observed for the 1,4-interstrand cross-link of the dinuclear 1,1/t,t compound. The potential significance of preassociation in determining kinetics of formation and structure of the adducts is discussed. The conformational flexibility of the cross-links is discussed in relation to their biological processing, especially protein recognition and repair, which are critical determinants of the cytotoxicity of these unique DNA-binding agents.     

Selective detection of 2-deoxyribonolactone in DNA

2-Deoxyribonolactone (L) is an oxidized abasic lesion that is produced by a variety of DNA damaging agents. It exhibits unique biological effects with respect to its proclivity to form DNA-protein cross-links and promutagenic base pairs. Recent evidence suggests that the levels of this lesion caused by oxidative stress are underestimated. We have developed a simple, selective method for detecting subpicomole amounts of L in DNA. The method takes advantage of the selective reaction of the butenolide (2) derived from beta-elimination from L with a biotinylated derivative of cysteine. This method will be useful for analyzing the levels of this oxidized abasic site in DNA.