Reaction of acid-activated mitomycin C with calf thymus DNA and model guanines: elucidation of the base-catalyzed degradation of N7-alkylguanine nucleosides

Mitomycin C (MC, 1) forms covalent adducts under acidic activating conditions (pH approximately 4) with deoxyguanosine, d(GpC), and guanine residues of calf thymus DNA. In the case of deoxyguanosine, five adducts arise from a common precursor, N7-(2' beta, 7'-diaminomitosen-1'-yl)-2'-deoxyguanosine (10a; not isolated), which hydrolyzes spontaneously via two pathways: scission of the glycosidic bond to form N7-(2' beta, 7'-diaminomitosen-1' alpha-yl)guanine (5) and its 1' beta-isomer (6) and imidazolium ring opening to generate three 2,6-diamino-4-hydroxy-5-(N-formyl-2' beta, 7'-diaminomitosen-1' beta-yl)pyrimidine (FAPyr) derivatives that are substituted at N6 by isomeric 2'-deoxyribose units [i.e., 1' beta-furanose (7), 1' alpha-furanose (8), and 1' beta-pyranose (9)]. The structures of 5-9 were determined by spectroscopic methods. The same five adducts were obtained from d(GpC), but only the guanine adducts 5 and 6 were formed in DNA. Adducts 7-9 interconvert during high-performance liquid chromatography (HPLC). The unexpected isomerization of the deoxyribose moiety of the initially formed 1' beta-furanose adduct 7 to those of 8 and 9 occurs upon imidazolium ring opening, as discerned by the course of imidazolium cleavage of the simple models N7-ethyl- and N7-methylguanosine and N7-methyl-2'-deoxyguanosine. All ring-opened N7-alkylguanosine derivatives studied here exist as a mixture of distinct N-formyl rotamers, manifested by multiple interconverting peaks on HPLC and in the 1H NMR spectra. In the UV spectra of such derivatives, a new and diagnostic maximum at 218 nm (at pH 7) is observed. Acid-activated MC is found to alkylate preferentially the Gua-N7 position in deoxyguanosine or d(GpC), in contrast to reductively activated MC, which preferentially alkylates the Gua-N2 position. This finding is explained by the different electronic structures of acid- and reduction-activated MC. In DNA, the N7 specificity of acid-activated MC is partially offset by steric factors.     

Sequence preferences of DNA interstrand cross-linking agents: dG-to-dG cross-linking at 5'-CG by structurally simplified analogues of mitomycin C

The nucleotide sequence preferences of the DNA interstrand cross-linking agents dehydroretronecine diacetate (DHRA), 2,3-bis(acetoxymethyl)-1-methylpyrrole (BAMP), dehydromonocrotaline, and dehydroretrorsine were studied by using synthetic DNA duplex fragments and polyacrylamide gel electrophoresis (PAGE). These agents have structural features in common with the reductively activated aziridinomitosene of mitomycin C (MC). Like MC, they preferentially cross-linked DNA duplexes containing the duplex sequence 5'-CG. For DHRA and BAMP interstrand cross-linked DNA duplexes, PAGE analysis of iron(II)-EDTA fragmentation reactions revealed the interstrand cross-links to be deoxyguanosine to deoxyguanosine (dG-to-dG), again analogous to DNA cross-links caused by MC. Unlike MC, DHRA could be shown to dG-to-dG cross-link a 5'-GC sequence. Furthermore, the impact of flanking sequence on the efficiency of interstrand cross-linking at 5'-CG was reduced for BAMP, with 5'-TCGA and 5'-GCGC being equally efficiently cross-linked. Possible origins of the 5'-CG sequence recognition common to all of the agents are discussed. A model is presented in which the transition state for the conversion of monoadducts to cross-links more closely resembles ground-state DNA at 5'-CG sequences.     

Reductive alkylation of DNA by mitomycin A, a mitomycin with high redox potential

The mitomycins are a group of antitumor antibiotics that covalently bind to DNA upon reductive activation. Mitomycin A (1b; MA) is more toxic than its clinically useful mitomycin C (1a; MC). The greater toxicity of mitomycin A has been previously attributed to its higher reduction potential. In this report, the DNA alkylation products of reductively activated MA were isolated and characterized by conversion to the known 7-amino mitosene-deoxyguanosine adducts. The three major adducts formed were identified as a monoadduct, N2-(2"beta-amino-7"-methoxymitosen-1"alpha-yl)- 2'-deoxyguanosine (5), a decarbamoyl monoadduct, N2-(2"beta-amino-10"-decarbamoyl-7"-methoxymitosen-1"alpha-y l)-2'- deoxyguanosine (6), and a bisadduct, N2-(2"beta-amino-10"-deoxyguanosin-N2-yl-7-methoxymitosen-1" alpha- yl)-2'-deoxyguanosine (7). Under all reductive activation conditions employed, MA selectively alkylated the 2-amino group of guanine in DNA, like MC. In addition, both MA and MC alkylated DNA and cross-linked oligonucleotides to a similar extent. However, variations in the reductive activation conditions (H2/PtO2, Na2S2O4, or enzymatic) affected the distribution of the three major MA adducts in a different manner than the distribution of MC adducts was affected. A mechanism is proposed wherein the 7-methoxy substituent of MA allows initial indiscriminate activation of either of the drugs' two electrophilic sites. While oxygen inhibited cross-linking by MC, similar aerobic conditions exhibited little influence on the cross-linking ability of MA. Hence, the greater toxicity of MA may be influenced by increased and nonselective activation and cross-link formation in both aerobic and anaerobic cells. This effect is a direct consequence of the higher redox potential of MA as compared to MC.     

Conformational analysis of site-specific DNA cross-links of cisplatin-distamycin conjugates

The requirement for novel platinum antitumor drugs led to the concept of synthesis of novel platinum drugs based on targeting cisplatin to various carrier molecules. We have shown [Loskotova, H., and Brabec, V. (1999) Eur. J. Biochem. 266, 392-402] that attachment of DNA minor-groove-binder distamycin to cisplatin changes several features of DNA-binding mode of the parent platinum drug. Major differences comprise different conformational changes in DNA and a considerably higher interstrand cross-linking efficiency. The studies of the present work have been directed to the analysis of oligodeoxyribonucleotide duplexes containing single, site-specific adducts of platinum-distamycin conjugates. These uniquely modified duplexes were analyzed by Maxam-Gilbert footprinting, phase-sensitive gel electrophoresis bending assay and chemical probes of DNA conformation. The results have indicated that the attachment of distamycin to cisplatin mainly affects the sites involved in the interstrand cross-links so that these adducts are preferentially formed between complementary guanine and cytosine residues. This interstrand cross-link bends the helix axis by approximately 35 degrees toward minor groove, unwinds DNA by approximately 95 degrees and distorts DNA symmetrically around the adduct. In addition, CD spectra of restriction fragments modified by the cisplatin-distamycin conjugates have demonstrated that distamycin moiety in the interstrand cross-links of these compounds interacts with DNA. This interaction facilitates the formation of these adducts. Hence, the structural impact of the specific interstrand cross-link detected in this study deserves attention when biological behavior of cisplatin derivatives targeted by oligopeptide DNA minor-groove-binders is evaluated.     

Exposure of mammalian cells to 60-Hz magnetic or electric fields: analysis for DNA single-strand breaks

Chinese hamster ovary (CHO) cells were exposed for 1 h to 60-Hz magnetic fields (0.1 or 2 mT), electric fields (1 or 38 V/m), or to combined magnetic and electric fields (2 mT and 38 V/m, respectively). Following exposure, the cells were lysed, and the DNA was analyzed for the presence of single-strand breaks (SSB), using the alkaline elution technique. No significant differences in numbers of DNA SSB were detected between exposed and sham-exposed cells. A positive control exposed to X-irradiation sustained SSB with a dose-related frequency. Cells exposed to nitrogen mustard (a known cross-linking agent) and X-irradiation demonstrated that the assay could detect cross-linked DNA under our conditions of electric and magnetic field exposures.     

Reactions of malonaldehyde and acetaldehyde with calf thymus DNA: formation of conjugate adducts

Our previous work has shown that treatment of nucleosides with malonaldehyde simultaneously with acetaldehyde affords stable conjugate adducts. In the present study we demonstrate that conjugate adducts are also formed in calf thymus DNA when incubated with the aldehydes. The adducts were identified in the DNA hydrolysates by their positive ion electrospray MS/MS spectra, by coelution with the 2'-deoxynucleoside standards, and, in the case of adducts exhibiting fluorescent properties, also by LC using a fluorescence detector. In the hydrolysates of double-stranded DNA (ds DNA), two deoxyguanosine and two deoxyadenosine conjugate adducts were detected and in single-stranded DNA (ss DNA) also, the deoxycytidine conjugate adduct was observed. The guanine base was the major target for the malonaldehyde-acetaldehyde conjugates and 2'-deoxyguanosine adducts were produced in ds DNA at levels of 100-500 adducts/10(5) nucleotides (0.7-3 nmol/mg DNA).     

Bioreductive activation of mitomycin C by DT-diaphorase.

The role of DT-diaphorase (DTD, EC 1.6.99.2) in the bioreductive activation of mitomycin C was examined using purified rat hepatic DTD. The formation of adducts with reduced glutathione (GSH), binding of [3H]mitomycin C to DNA, and mitomycin C-induced DNA interstrand cross-linking were used as indicators of bioactivation. Mitomycin C was metabolized by DTD in a pH-dependent manner with increasing amounts of metabolism observed as the pH was decreased from 7.8 to 5.8. The major metabolite observed during DTD-mediated reduction of mitomycin C was 2,7-diaminomitosene. GSH adduct formation, binding of [3H]mitomycin C and mitomycin C-induced DNA interstrand cross-linking were observed during DTD-mediated metabolism. In agreement with the pH dependence of metabolism, increased bioactivation was observed at lower pH values. Temporal studies and experiments using authentic material showed that 2,7-diaminomitosene could be further metabolized by DTD resulting in the formation of mitosene adducts with GSH. DNA cross-linking during either chemical (sodium borohydride) or enzymatic (DTD) mediated reduction of mitomycin C could be observed at pH 7.4, but it increased as the pH was decreased to 5.8, showing the critical role of pH in the cross-linking process. These data provide unequivocal evidence that the obligate two-electron reductase DTD can bioactivate mitomycin C to reactive species which can form adducts with GSH and DNA and induce DNA cross-linking. The use of mitomycin C may be a viable approach to the therapy of tumors high in DTD activity, particularly when combined with strategies to lower tumor pH.     

The mode of action of cytotoxic and antitumor 1-nitroacridines. III. In vivo interstrand cross-linking of DNA of mammalian or bacterial cells by 1-nitroacridines

To define a critical lesion in presumable target DNA cause in vivo by the antitumor and cytotoxic 1-nitroacridines, Ehrlich ascites tumor (Eat) cells implanted into mice, HeLa cells grown in monolayer culture or Bacillus subtilis SB 1058 strain cells were exposed to Ledakrin [Nitracrine; 1-nitro-9-(3'-dimethylamino-n-propylamino)acridine], its non-antitumor congeners, or mitomycin C tested for comparison; total intracellular DNA was isolated from control or treated cells and denatured by heat, alkali or formamide, after which the chemically-induced fraction of interstrand cross-linked DNA molecules was assessed by thermal denaturation-renaturation curve analysis, hydroxylapatite column chromatography, or partitioning in a Dextran T500-polyethylene glycol 6000 biphasic system. Ledakrin, as compared to mitomycin C, was a very effective cross-linking agent, inducing one covalent cross-link per approx. 20 X 10(3) (B. subtilis), 56 X 10(3) (HeLa) or 80 X 10(3) (Eat) DNA base pairs. The first cross-links were introduced in B. subtilis cell genomes at minimal bactericidal concentrations of Ledakrin of mitomycin C. Ledakrin failed to induce discernible cross-linking of bihelical DNA when complexed with in cell-free system. Unlike the other two 1-nitroacridines which cross-linked DNA of cultured HeLa or B. subtilis cells, the non-antitumor 2-, 3- or 4-nitroacridines did not cause such effect and diminished cross-linking by Ledakrin or mitomycin C. Hence, upon metabolic activation in mammalian or bacterial cell Ledakrin and, most probably other 1-nitroacridines, become very effective DNA cross-linking agents and such effects appear to be responsible for the antitumor and potent cytotoxic activities of 1-nitroacridines.     

Effect of varying the exposure and 3H-thymidine labeling period upon the outcome of the primary hepatocyte DNA repair assay

The results presented in this report demonstrate that an 18–20 hour exposure/³H-thymidine DNA labeling period is superior to a 4 hour incubation interval for general genotoxicity screening studies in the rat primary hepatocyte DNA repair assay. When DNA damaging agents which give rise to bulky-type DNA base adducts such as 2-acetylaminofluorene, aflatoxin Bi and benzidine were evaluated, little or no difference was observed between the 4 hour or an 18–20 hour exposure/labeling period. Similar results were also noted for the DNA ethylating agent diethylnitrosamine. However, when DNA damaging chemicals which produce a broader spectrum of DNA lesions were studied, differences in the amount of DNA repair as determined by autoradiographic analysis did occur. Methyl methanesulfonate and dimethylnitrosamine induced repairable DNA damage that was detected at lower dose levels with the 18–20 hour exposure/labeling period. Similar results were also observed for the DNA cross-linking agents, mitomycin C and nitrogen mustard. Ethyl methanesulfonate produced only a marginal amount of DNA repair in primary hepatocytes up to a dose level of 10^–3M during the 4 hour incubation period, whereas a substantial amount of DNA repair was detectable at a dose level of 2.5 × 10^–4M when the 18–20 hour exposure/labeling period was employed. The DNA alkylating agent 4-nitroquinoline-1-oxide, which creates DNA base adducts that are slowly removed from mammalian cell DNA, induced no detectable DNA repair in hepatocytes up to a toxic dose level of 2 × 10^–5M with the 4 hour exposure period, whereas a marked DNA repair response was observed at 10^–5M when the 18–20 hour exposure/labeling period was used.Abbreviations 2AAF 2-acetylaminofluorene - AB₁ aflatoxin B₁ - BENZ benzidine - DEB diepoxybutane - DEN diethylnitrosamine - DMN dimethylnitrosamine - EMS ethyl methanesulfonate - MITC mitomycin C - MMS methyl methanesulfonate - NG mean net nuclear grain counts - NM nitrogen mustard - 4NQO 4-nitroquinoline-N-oxide     

Use of oligonucleotides to define the site of interstrand cross-links induced by Adriamycin.

It has been known for several years that Adriamycin forms adducts and interstrand cross-links when reacted for long periods of time with bacterial and mammalian DNA in vitro, with the cross-link being restricted to 2 bp elements containing GpC sequences. The self-complementary 20mer deoxyoligonucleotide TA4T4GCA4T4A has been used in this study as a model of the apparent G-G cross-linking site at GpC sequences. The rate of formation of cross-links, as well as the dependence on both Adriamycin and Fe(III) concentration, were similar with this oligonucleotide as compared with calf thymus DNA. The cross-linking was demonstrated on both denaturing and non-denaturing sequencing gels. The half-life of the G-G cross-link was 40 h, consistent with that implied with high molecular weight, heterogeneous sequence DNA. Exonuclease III digests of adducts formed with 20mer deoxyoligonucleotides containing single, central G-G, G-I and I-I potential cross-links revealed that a guanine residue is required at both ends of the cross-link. No cross-linking was observed with a similar oligonucleotide containing only a single central (G.C) bp.     

Structure and formation of a stable histidine-based trifunctional cross-link in skin collagen

A stable nonreducible trifunctional cross-linking amino acid has been isolated from mature bovine skin collagen fibrils. Previous cross-link peptide isolations and amino acid analyses indicate the compound has properties identical with those of hydroxyaldolhistidine. Its newly proposed structure was verified using fast atom bombardment mass spectrometry, and 1H and 13C nuclear magnetic resonance. The data indicated that the cross-link consists of the prosthetic groups from one residue each of histidine, hydroxylysine, and lysine. The 1H and 13C nuclear magnetic resonance data indicated that imidazole C-2 of histidine is linked to C-6 of norleucine (epsilon-deaminated lysine residue) which in turn is linked to the C-6 amino group of hydroxylysine. Based on the trivial names for other cross-linking residues found in collagen and elastin it was given the name histidinohydroxylysinonorleucine. In vitro incubation studies for up to 24 weeks, in aqueous solution at physiological pH and ionic strength, using 6-month-old bovine embryo skin demonstrated a one-to-one stoichiometric relationship between the disappearance of the labile reducible bifunctional cross-link dehydrohydroxylysinonorleucine and the appearance of histidinohydroxylsinonorleucine. These results can partially explain the previously observed disappearance of dehydrohydroxylysinonorleucine with chronological age.     

Alternative conformations of DNA modified by N-2-acetylaminofluorene

Modification of DNA by the carcinogen N-acetoxy-N-2-acetylaminofluorene gives two adducts, a major one at the C-8 position of guanine and a minor one at the N-2 position with differing conformations. Binding at the C-8 position results in a large distortion of the DNA helix referred to as the “base displacement model” with the carcinogen inserted into the DNA helix and the guanosine displaced to the outside. The result is increased susceptibility to nuclease S, digestion due to the presence of large, single-stranded regions in the modified DNA. In contrast, the N-2 adduct results in much less distortion of the helix and is less susceptible to nuclease S₁ digestion. A third and predominant adduct is formed in vivo, the deacetylated C-8 guanine adduct. The conformation of this adduct has been investigated using the dimer dApdG as a model for DNA. The attachment of aminofluorene (AF) residues introduced smaller changes in the circular dichroism (CD) spectra of dApdG than binding of acetylaminofluorene (AAF) residues. Similarly, binding of AF residues caused lower upfield shifts for the H-2 and H-8 protons of adenine than the AAF residues. These results suggest that AF residues are less stacked with neighboring bases than AAF and induce less distortion in conformation of the modified regions than AAF. An alternative conformation of AAF-modified deoxyguanosine has been suggested based on studies of poly(dG-dC)·poly(dG-dC). Modification of this copolymer with AAF to an extent of 28% showed a CD spectrum that had the characteristics of the left-handed Z conformation seen in unmodified poly-(dG-dC)·poly(dG-dC) at high ethanol or salt concentrations. Poly(dG)·poly(dC), which docs not undergo the B to Z transition at high ethanol concentrations, did not show this type of conformational change with high AAF modification. Differences in conformation were suggested by single-strand specific nuclease S₁ digestion and reactivity with anticytidine antibodies. Highly modified poly(dG-dC)·poly(dG-dC) was almost completely resistant to nuclease S₁ hydrolysis, while, modified DNA and poly(dG)·poly(dC) are highly susceptible to digestion. Two possible conformations for deoxyguanosine modified at the C-8 position by AAF are compared depending on whether its position is in alternating purine-pyrimidine sequences or random sequence DNA.     

Reassignment of the guanine-binding mode of reduced mitomycin C

Mitomycin C (1) is a clinically used antitumor antibiotic that binds covalently to deoxyribonucleic acid under reductive or acidic catalysis. We have determined the structures of the adducts resulting from attack of reductively activated 1 on the dinucleoside phosphate d(GpC) to be N2-(2' beta, 7'-diaminomitosen-1'alpha-yl)-2'-deoxyguanosine (2) and its 1' beta-isomer (3). This represents a revision of the previously reported structures for these adducts in that the mitomycin residue is linked to the N2- rather than O6-position of 2'-deoxyguanosine. This revision is the result of applying to the mitomycin case a newly developed general method that leads to unambiguous assignment of the linkage position in complex alkylated guanosines. The method as described here takes advantage of the resolution enhancement gained by calculation of the second derivatives of absorbance Fourier transform infrared spectra. In addition, we present 1H NMR data that corroborate the assigned structures of 2 and 3 and that should serve as a useful reference for future investigations into the binding of mitomycin C to DNA. The convenient synthesis of adducts 2 and 3 from deoxyguanosine and mitomycin C reported here should facilitate such investigations as well. Furthermore, we demonstrate a useful acetylation procedure for adducts and metabolites of mitomycin C that furnishes spectroscopically superior chemical derivatives (e.g., triacetates 4 and 5, derived from acetylation of adducts 2 and 3).     

Knockdown of αII spectrin in normal human cells by siRNA leads to chromosomal instability and decreased DNA interstrand cross-link repair

Nonerythroid α-spectrin (αIISp) is a structural protein involved in repair of DNA interstrand cross-links and is deficient in cells from patients with Fanconi anemia (FA), which are defective in ability to repair cross-links. In order to further demonstrate the importance of the role that αIISp plays in normal human cells and in the repair defect in FA, αIISp was knocked down in normal cells using siRNA. Depletion of αIISp in normal cells by siRNA resulted in chromosomal instability and cellular hypersensitivity to DNA interstrand cross-linking agents. An increased number of chromosomal aberrations were observed and, following treatment with a DNA interstrand cross-linking agent, mitomycin C, cells showed decreased cell growth and survival and decreased formation of damage-induced αIISp and XPF nuclear foci. Thus depletion of αIISp in normal cells leads to a number of defects observed in FA cells, such as chromosome instability and a deficiency in cross-link repair.     

The pH-dependent structure of calf thymus DNA studied by Raman spectroscopy

The pH-dependent structure of calf thymus DNA is analyzed using Raman spectroscopy. The Raman spectra in the acidic region demonstrate that denaturation occurs in several steps. The binding of H⁺ to adenine and cytosine residues is accompanied by a decrease in the percentage of DNA in the B-conformation and a concurrent increase in a conformation most probably related to the C-form. The denaturation of DNA is observed at pH 3.3 and parallels the protonation of guanine bases. The Raman spectra of calf thymus DNA in the basic region (above pH 10) show that guanine residues are deprotonated at a lower pH value than are thymine residues. In addition, Raman spectra in the basic region detect conformational changes of the phosphate backbone different from those found in the acidic region.     

Duplex oligodeoxyribonucleotides cross-linked by mitomycin C at a single site: synthesis, properties, and cross-link reversibility

Oligodeoxyribonucleotides cross-linked by reductively activated mitomycin C (MC) were prepared and purified for the first time. The cross-linked products were structurally characterized by nucleoside and MC-nucleoside adduct analysis. Optimal conditions were established for the cross-linking reaction, resulting in high yields, typically in the 20-50% range. Nuclease digests of the cross-linked oligonucleotides yielded the same bifunctional MC-deoxyguanosine adduct as that previously isolated from DNA exposed to MC in vitro and in vivo [Tomasz et al. (1987) Science 235, 1204]. The cross-linked oligonucleotides displayed broad thermal melting profiles, greatly increased Tm, and complex circular dichroism spectra. Phosphodiester linkages at the cross-link were resistant to spleen exonuclease, nuclease P1, and TaqI and ClaI restriction endonucleases; snake venom diesterase action was uninhibited. The cross-links are stable to heat at neutral pH but are removed by treatment in hot piperidine or by the reducing agents Na2S2O4 and dithiothreitol. Mechanisms are proposed for these reactions. These studies define optimal methods for introducing mitomycin cross-links into DNA fragments at a specific site, providing a versatile tool to study the effects of the MC cross-links on DNA structure and function.     

Inhibition of DNA cross-linking by mitomycin C by peroxidase-mediated oxidation of mitomycin C hydroquinone.

Mitomycin C requires reductive activation to cross-link DNA and express anticancer activity. Reduction of mitomycin C (40 microm) by sodium borohydride (200 microm) in 20 mm Tris-HCl, 1 mm EDTA at 37 degrees C, pH 7.4, gives a 50-60% yield of the reactive intermediate mitomycin C hydroquinone. The hydroquinone decays with first order kinetics or pseudo first order kinetics with a t(12) of approximately 15 s under these conditions. The cross-linking of T7 DNA in this system followed matching kinetics, with the conversion of mitomycin C hydroquinone to leuco-aziridinomitosene appearing to be the rate-determining step. Several peroxidases were found to oxidize mitomycin C hydroquinone to mitomycin C and to block DNA cross-linking to various degrees. Concentrations of the various peroxidases that largely blocked DNA cross-linking, regenerated 10-70% mitomycin C from the reduced material. Thus, significant quantities of products other than mitomycin C were produced by the peroxidase-mediated oxidation of mitomycin C hydroquinone or products derived therefrom. Variations in the sensitivity of cells to mitomycin C have been attributed to differing levels of activating enzymes, export pumps, and DNA repair. Mitomycin C hydroquinone-oxidizing enzymes give rise to a new mechanism by which oxic/hypoxic toxicity differentials and resistance can occur.     

Characterization of bifunctional adducts produced in DNA by trans-diamminedichloroplatinum(II)

The cancer chemotherapeutic drug cis-diamminedichloroplatinum(II) (cis-DDP) produces bifunctional reactions with DNA which appear critical to its toxic action. The relative inefficacy of the isomer trans-DDP results from its production of predominantly monofunctional adducts in DNA. However, trans-DDP is also toxic and this is presumed to result from bifunctional reaction. These reactions have been characterized by platinating pure DNA followed by enzyme digestion, HPLC separation and analysis by atomic absorption and nuclear magnetic resonance (NMR). Bifunctional adducts occur between deoxyguanosine (dG) and either deoxyadenosine (dA), deoxycytidine (dC) or another dG. Although dG-Pt-dG occurs in both double-stranded (approximately 40% of total adducts) and single-stranded DNA (approximately 60%) there is a marked preference for formation of dG-Pt-dC in double-stranded DNA (approximately 50%) and dG-Pt-dA in single-stranded DNA (approximately 35%). Only dG-Pt-dG forms rapidly; the other adducts derive from rapid formation of a monofunctional dG-Pt and further reaction with dA or dC over many hours.     

Steric control of DNA interstrand cross-link sites of <Emphasis Type="Italic">trans</Emphasis> platinum complexes: specificity can be dictated by planar nonleaving groups

trans -dichloroplatinum(II) complexes exhibit antitumor activity violate the classical structure-activity relationships of platinum(II) complexes. These novel “nonclassical”trans platinum complexes also comprise those containing planar aromatic amines. Initial studies have shown that these compounds form a considerable amount of DNA interstrand cross-links (up to ∼30%) with a rate markedly higher than clinically ineffective transplatin. The present work has shown, using Maxam-Gilbert footprinting, that trans-[PtCl₂(NH₃)(quinoline)] and trans-[PtCl₂(NH₃)(thiazole)], representatives of the group of new antitumor trans-dichloroplatinum complexes containing planar amines, preferentially form DNA interstrand cross-links between guanine residues at the 5′-GC-3′ sites. Thus, DNA interstrand cross-linking by trans-[PtCl₂(NH₃)(quinoline)] and trans-[PtCl₂(NH₃)(thiazole)] is formally equivalent to that by antitumor cisplatin, but different from clinically ineffective transplatin which preferentially forms these adducts between complementary guanine and cytosine residues. This result shows for the first time that simple chemical modification of the structure of an inactive compound alters its DNA binding site into a DNA adduct of an active drug. Received: 6 January 2000 / Accepted: 8 March 2000     

Cytotoxicity and mutagenicity of aflatoxin dichloride in normal and repair deficient diploid human fibroblasts

The cytotoxic and mutagenic effect of aflatoxin B1-dichloride (AFB1-Cl2), a direct-acting carcinogen which is a model for the proposed ultimate reactive metabolite of AFB1 (the 2,3-epoxide), was compared in normal, repair-proficient, diploid human fibroblasts and in complementation Group A xeroderma pigmentosum cells (XP12BE) which are virtually incapable of excision repair of DNA damage induced by ultraviolet radiation, the 7,8-diol-9,10-epoxide of benzo[alpha]pyrene, and several reactive aromatic amide derivatives. The XP cells were significantly more sensitive than normal to the cytotoxic and mutagenic effects of AFB1-Cl2, not only as a function of concentration administered but also of the number of AFB1-Cl2 residues initially bound to DNA. Cytotoxicity was determined from survival of colony-forming ability; resistance to 6-thioguanine was the genetic marker used for mutagenicity. We compared the rate of loss of AFB1-Cl2-DNA adducts from cells treated and held in the non-dividing state (confluent) over several days, as well as their ability to recover from the potentially mutagenic and/or cytotoxic effects of the agent. AFB1-Cl2 residues were lost from both strains of cells and both exhibited a gradual increase in survival. However, the rate of loss of adducts from the DNA in the normal cells was more rapid than in XP cells and they exhibited recovery from higher doses of AFB1-Cl2 than XP cells. The major primary DNA adduct formed in the human cells and in isolated DNA was a chemically unstable guanine derivative which could undergo a change in structure with time posttreatment to form a more stable secondary adduct. The cytotoxic effect of AFB1-Cl2 was highly correlated with the presence of either of these guanine adducts. Evidence suggests that the primary adduct is an N7-guanine adduct. The kinetics of the loss of this guanine and its transformation into the more stable secondary adduct resembled that reported recently for the major primary DNA adduct formed by the reaction of AFB1 at the N-7 position of guanine in the DNA of normal and XP cells and its transformation into the putative AFB1-ring opened triamino pyrimidyl structure.