ESR studies on the active intermediate in the enzymatic reduction of the Fe-bleomycin complex

The spin trapping method was applied to elucidate the active intermediate during the enzymatic reduction of Fe(III)-bleomycin in the presence of NADPH-cytochrome P-450 reductase and O2. Although the hydroxyl adducts to spin traps were observed, the adduct formation was not inhibited by catalase nor by SOD. Furthermore, in Tris-HCl buffer, no Tris adduct to the spin trap was observed. The results lead to the conclusion that there is no participation of free OH radical in the reactive intermediate in this reduction system. Effect of phosphate buffer on the reactivity of Fe(II)-bleomycin and spin state of Fe(III)-bleomycin were discussed.     

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.     

Microsome-stimulated activation of ferrous bleomycin in the presence of DNA

The inhibition of Fe(II)-bleomycin activation, by a large excess of DNA, is overcome by rat liver microsomes in the presence of NADPH. This release of inhibition, as indicated by increased yields of base propenal from DNA scission, is enhanced by menadione, is inhibited by superoxide dismutase, and is therefore dependent on superoxide anion. Microsomal activation of Fe(II)-bleomycin doubles the stoichiometry of base propenal yield compared to that obtained upon self-activation of the drug; 0.5 mol of base propenal is formed and 0.5 mol of NADPH is oxidized per mol of Fe(II)-bleomycin. In the presence of a large excess of DNA, Cu(II)-bleomycin is not reduced and Fe(III)-bleomycin is neither reduced nor activated by microsomes in cases where activation of Fe(II)-bleomycin is maximal. We suggest that in vivo, electron transport enzymes at or near the nucleus can stimulate the activation of Fe(II)-bleomycin under conditions where self-activation does not readily occur.     

Copper(I)-bleomycin: structurally unique complex that mediates oxidative DNA strand scission

Copper(I)-bleomycin [Cu(I) X BLM] was characterized in detail by 13C and 1H NMR. Unequivocal chemical shift assignments for Cu(I) X BLM and Cu(I) X BLM X CO were made by two-dimensional 1H-13C correlated spectroscopy and by utilizing the observation that Cu(I) X BLM was in rapid equilibrium with Cu(I) and metal-free bleomycin, such that individual resonances in the spectra of BLM and Cu(I) X BLM could be correlated. The binding of Cu(I) by bleomycin involves the beta-aminoalaninamide and pyrimidinyl moieties, and possibly the imidazole, but not N alpha of beta-hydroxyhistidine. Although no DNA strand scission by Cu(II) X BLM could be demonstrated in the absence of dithiothreitol, in the presence of this reducing agent substantial degradation of [3H]DNA was observed, as was strand scission of cccDNA. DNA degradation by Cu(I) X BLM was shown not to depend on contaminating Fe(II) and not to result in the formation of thymine propenal; the probable reason(s) for the lack of observed DNA degradation in earlier studies employing Cu(II) X BLM and dithiothreitol was (were) also identified. DNA strand scission was also noted under anaerobic conditions when Cu(II) X BLM and iodosobenzene were employed. If it is assumed that the mechanism of DNA degradation in this case is the same as that under aerobic conditions (i.e., with Cu(I) X BLM + O2 in the presence of dithiothreitol), then Cu X BLM must be capable of functioning as a monooxygenase in its degradation of DNA.     

Liver Nuclear Nadph-Cytochrome P-450 Reductase May be Involved in Redox Cycling of Bleomycin-Fe(III), Oxy Radical Formation and DNA Damage

When NADPH-cytochrome P-450 reductase isolated from rat liver microsomes was aerobically incubated with bleomycin, FeCl₃, NADPH and DNA parallel NADPH and oxygen were consumed and malondialdehyde was formed. A similar parallelism of NADPH- and oxygen-consumption and malondialdehyde formation was observed when ceil nuclei isolated from rat liver were incubated under the same conditions. The formation of malondialdehyde which was identified by HPLC and which was most likely released from oxidative cleavage of deoxyribose of nuclear DNA required oxygen, bleomycin, FeCl₃ and NADPH. This indicates that a nuclear NADPH-enzyme, presumably NADPH-cytochrome P-450 reductase, is able to redox cycle a bleomycin-iron-complex which in the reduced form can activate oxygen to a DNA-damaging reactive species. The data suggest that the activity of this enzyme in the cell nucleus could play an important role in the cytotoxicity of bleomycin in tumor cells.     

Liver Nuclear Nadph-Cytochrome P-450 Reductase May be Involved in Redox Cycling of Bleomycin-Fe(III), Oxy Radical Formation and DNA Damage

When NADPH-cytochrome P-450 reductase isolated from rat liver microsomes was aerobically incubated with bleomycin, FeCl₃, NADPH and DNA parallel NADPH and oxygen were consumed and malondialdehyde was formed. A similar parallelism of NADPH- and oxygen-consumption and malondialdehyde formation was observed when ceil nuclei isolated from rat liver were incubated under the same conditions. The formation of malondialdehyde which was identified by HPLC and which was most likely released from oxidative cleavage of deoxyribose of nuclear DNA required oxygen, bleomycin, FeCl₃ and NADPH. This indicates that a nuclear NADPH-enzyme, presumably NADPH-cytochrome P-450 reductase, is able to redox cycle a bleomycin-iron-complex which in the reduced form can activate oxygen to a DNA-damaging reactive species. The data suggest that the activity of this enzyme in the cell nucleus could play an important role in the cytotoxicity of bleomycin in tumor cells.     

Copper-dependent cleavage of DNA by bleomycin

DNA strand scission by bleomycin in the presence of Cu and Fe was further characterized. It was found that DNA degradation occurred readily upon admixture of Cu(I) or Cu(II) + dithiothreitol + bleomycin, but only where the order of addition precluded initial formation of Cu(II)--bleomycin or where sufficient time was permitted for reduction of the formed Cu(II)--bleomycin to Cu(I)--bleomycin. DNA strand scission mediated by Cu + dithiothreitol + bleomycin was inhibited by the copper-selective agent bathocuproine when the experiment was carried out under conditions consistent with Cu chelation by bathocuproine on the time scale of the experiment. Remarkably, it was found that the extent of DNA degradation obtained with bleomycin in the presence of Fe and Cu was greater than that obtained with either metal ion alone. A comparison of the sequence selectivity of bleomycin in the presence of Cu and Fe using 32P-end-labeled DNA duplexes as substrates revealed significant differences in sites of DNA cleavage and in the extent of cleavage at sites shared in common. For deglycoblemycin and decarbamoylbleomycin, whose metal ligation is believed to differ from that of bleomycin itself, it was found that the relative extents of DNA cleavage in the presence of Cu were not in the same order as those obtained in the presence of Fe. The bleomycin-mediated oxygenation products derived from cis-stilbene were found to differ in type and amount in the presence of added Cu vs. added Fe. Interestingly, while product formation from cis-stilbene was decreased when excess Fe was added to a reaction mixture containing 1:1 Fe(III) and bleomycin, the extent of product formation was enhanced almost 4-fold in reactions that contained 5:1, as compared to 1:1, Cu and bleomycin. The results of these experiments are entirely consistent with the work of Sugiura [Sugiura, Y. (1979) Biochem. Biophys. Res. Commun. 90, 375-383], who first demonstrated the generation of reactive oxygen species upon admixture of O2 and Cu(I)--bleomycin.     

P-3A and (−)-desacetamido P-3A: demonstration and Study of their effective functional cleavage of duplex DNA

A study of the Fe(II) complexes of P-3A (1) and (−)-desacetamido P-3A (2) abilities to cleave duplex DNA was conducted through examination of single-strand and double-strand cleavage of supercoiled φX174 RFI DNA (Form I) in the presence of O₂ to produce relaxed (Form II) and linear (Form III) DNA, respectively. Like Fe(II)-bleomycin A₂ and deglycobleomycin A₂, Fe(II)-1 and 2 effectively produced both single- and double-strand cleavage of supercoiled φX174 DNA. Unlike Fe(II)-bleomycin A₂ or deglycobleomycin A₂, Fe(II)-1 and 2 were found to cleave duplex w794 DNA with no discemible sequence selectively suggesting that the polynucleotide recognition of the C-terminus tetrapeptide S subunit of the bleomycins including the bithiazole may dominate the bleomycin A₂ DNA cleavage selectivity.     

DNA strand scission by enzymatically reduced mitomycin C: evidence for participation of the hydroxyl radical in the DNA damage

Phage DNA, as well as plasmid and mammalian DNA's, were exposed to a superoxide and hydroxyl radical-generating system containing NADPH-cytochrome P-450 reductase and mitomycin C, both with and without added Fe3+-ADP, in phosphate buffer at pH 7.5. The generation of superoxide (O2-.) and hydroxyl (.OH) radicals in the system was demonstrated by using ESR spectrometry with N-tert -butyl-alpha-phenylnitrone (PBN) as a spin trapping agent. Only the lambda DNA isolated after exposure to the O2-./.OH-generating system containing many lower molecular weight DNA fragments indicating DNA strand breaks. This breakage was completely inhibited by a .OH radical scavenger (sodium benzoate) and by catalase, but only slightly by superoxide dismutase. Thyroid and plasmid DNA's were both cleaved when exposed to the O2-./.OH-generating systems. It is suggested that the mechanism of DNA scission by mitomycin C described here closely resembles that induced by the anthracycline drugs.     

Oxygen transfer from bleomycin-metal complexes

Both Fe(III) and Cu(II) complexes of bleomycin (BLM), but not N-acetyl BLM . Fe(III), mediated the transfer of oxygen from iodosobenzene to organic substrates. In analogy with results obtained using certain cytochrome P-450 analogs, cis-stilbene was converted cleanly to the respective oxide, while no more than traces of trans-stilbene oxide were formed from trans-stilbene under identical conditions. The possible relevance of these observations to the degradation of DNA by bleomycin was also studied. In both the presence and absence of O2, BLM . Cu(II) . C6H5IO effected DNA degradation, as judged by the release of [3H]thymine from radiolabeled Escherichia coli DNA. These findings provide a valuable new assay system for the study of bleomycin analogs and suggest the possibility that bleomycin may function as an "oxygen transferase" in its degradation of DNA in situ.     

Analysis of products formed during bleomycin-mediated DNA degradation

By the use of DNA, copolymers of defined nucleotide composition, and a synthetic dodecanucleotide having putative bleomycin cleavage sites in proximity to the 5'- and 3'-termini, the products formed concomitant with DNA strand scission have been isolated and subjected to structural identification and quantitation via direct comparison with authentic synthetic samples. The products of DNA strand scission by Fe(II)-bleomycin include oligonucleotides having each of the four possible nucleoside 3'-(phosphoro-2'-O-glycolates) at their 3'-termini, as well as the four possible base propenals. At least for 3-(adenin-9'-yl)propenal and 3-(thymin-1'-yl)propenal, the products formed were exclusively of the trans configuration.     

A comparative study of the interactions of bleomycin with nuclei and purified DNA

Fe(III)-bleomycin associates strongly with rat liver nuclei and binds to nuclear DNA. Metal-free and Cu(II)-bleomycin, however, do not bind to nuclei. The treatment of nuclei with activated iron-bleomycin results in nucleic base and base propenal release from the DNA, and also gives membrane peroxidation. Isolation and quantitation of the base propenals and free bases released subsequent to activated bleomycin treatment reveal an alteration in the stoichiometry of these products compared to those released from purified DNA. With nuclei, significantly less propenal is formed, although the yield of free base is equivalent to that from purified DNA. The membrane peroxidation products from nuclei are the same as those obtained from microsomal membranes treated with activated bleomycin. Superoxide dismutase inhibits the membrane peroxidation but has no effect on the DNA breakage reactions. The results implicate a role for iron in mediating the in vivo action of bleomycin and also reveal a potentially toxic effect, membrane peroxidation, separate from DNA damage.     

Stimulatory effect of ascorbate on iron transfer from bleomycin to apotransferrin

The chemotherapeutic agent, bleomycin, forms a 1:1complex with both Fe(III) and Fe(II). The rate offerric ion transfer from bleomycin toapotransferrin is rather slow. However, when ascorbate was added toFe(III)-bleomycin priorto exposure to apotransferrin, the transfer rate was markedly increased. Ascorbatereadilyreduces Fe(III)-bleomycin to Fe(II)-bleomycin. A second order rate constant of 2.4 mM min wasestimated for this reaction. Fe(II)-bleomycinimmediately combines with O 2 , generating the so-called'acti-vatedbleomycin' complex. The data suggest that a reduced form of iron-bleomycin more readilydonatesits iron ion to apotransferrin. Reoxidation of ferrous ions, andFe(III)-transferrin formation occur rapidly.     

DNA strand scission by iron complexes of meso-tetra(N-methylpyridyl)porphines

The DNA strand scission activities of three positional isomers of Fe(III) meso-tetra(N-methylpyridyl)porphine (Fe(III)TnMPyP, where n = 2, 3 or 4) have been investigated using PM2 DNA as a substrate. A significant degree of strand scission activity was noted in the presence of oxygen without the addition of a reducing agent. This activity was probably due to the presence of reducing agents in the agarose gels used to separate the DNA forms, as higher levels were recorded with reducing agents added to the strand scission mixture. The relative order of strand scission activity in the absence of added reducing agents was found to be Fe(III)T2MPyP greater than Fe(III)T4MPyP greater than Fe(III)T3MPyP. Comparative studies were also made with Fe(II)bleomycin. High concentrations of some reducing agents inhibited strand scission. Oxygen was required to produce optimal strand scission activity for all three porphyrins. It was also noted from spectroscopic measurements that the reduced porphyrins were degraded in the presence of oxygen. Studies with a series of potential strand scission inhibitors suggest that hydrogen peroxide and possibly peroxy radicals are intermediates in the reaction mechanism, while diffusible hydroxyl radicals appear to be excluded. However, superoxide radicals cannot be ruled out.     

Inactivation of glutamine synthetase by a purified rabbit liver microsomal cytochrome P-450 system

Several mixed-function oxidation systems catalyze inactivation of Escherichia coli glutamine synthetase and other key metabolic enzymes. In the presence of NADPH and molecular oxygen, highly purified preparations of cytochrome P-450 reductase and cytochrome P-450 (isozyme 2) from rabbit liver microsomes catalyze enzyme inactivation. The inactivation reaction is stimulated by Fe(III) or Cu(II) and is inhibited by catalase, Mn(II), Zn(II), histidine, and the metal chelators o-phenanthroline and EDTA. The inactivation of glutamine synthetase is highly specific and involves the oxidative modification of a histidine in each glutamine synthetase subunit and the generation of a carbonyl derivative of the protein which forms a stable hydrazone when treated with 2,4-dinitrophenylhydrazine. We have proposed that the mixed-function oxidation system (the cytochrome P-450 system) produces Fe(II) and H2O2 which react at the metal binding site on the glutamine synthetase to generate an activated oxygen species which oxidizes a nearby susceptible histidine. This thesis is supported by the fact that (a) Mn(II) and Zn(II) inhibit inactivation and also interfere with the reduction of Fe(III) to Fe(II) by the P-450 system; (b) Fe(II) and H2O2 (anaerobically), in the absence of a P-450 system, catalyze glutamine synthetase inactivation; (c) inactivation is inhibited by catalase; and (d) hexobarbital, which stimulates the rate of H2O2 production by the P-450 system, stimulates the rate of glutamine synthetase inactivation. Moreover, inactivation of glutamine synthetase by the P-450 system does not require complex formation because inactivation occurs when the P-450 components and the glutamine synthetase are separated by a semipermeable membrane. Also, if endogenous catalase is inhibited by azide, rabbit liver microsomes catalyze the inactivation of glutamine synthetase.     

Copper-bleomycin has no significant DNA cleavage activity

In contrast to a very recent report [Ehrenfeld, G. M., Rodriguez, L. O., Hecht, S. M., Chang, C., Basus, V. J., & Oppenheimer, N. J. (1985) Biochemistry 24, 81-92], the present careful reexamination demonstrated that copper-bleomycin systems have no significant DNA cleavage activity. In the presence of dithiothreitol, the bleomycin-Cu(II) complex showed little activity for DNA degradation. The DNA strand scission by the Cu(I)-bleomycin-dithiothreitol system was remarkably depressed by deferoxamine rather than by bathocuproine, suggesting the effect of trace amounts of contaminating iron in the experiments. It seems highly unlikely that the DNA breakage activity due specifically to the Cu(I)-bleomycin complex system is substantially strong. Our results indicate that the metal really relevant to the DNA cleavage by bleomycin is iron not copper.     

Oxidative cell wall damage mediated by bleomycin-Fe(II) in Saccharomyces cerevisiae.

Bleomycin mediates cell wall damage in the yeast Saccharomyces cerevisiae. Bleomycin treatments in the presence of Fe(II) increased the rate of spheroplast formation by lytic enzymes by 5- to 40-fold. Neither Fe(III) nor other tested ions caused significant cell wall damage in the presence of bleomycin. The effect of bleomycin-Fe(II) on the cell wall mimicked the characteristics of bleomycin-Fe(II)-mediated DNA damage in dependence on aeration, inhibition by ascorbate, and potentiation by submillimolar concentrations of sodium phosphate. Bleomycin-mediated cell wall damage was time and dose dependent, with incubations as short as 20 min and drug concentrations as low as 3.3 x 10(-7)M causing measurable cell wall damage in strain CM1069-40. These times and concentrations are within the range of effectiveness for bleomycin-mediated DNA damage and for the cytotoxicity of the drug. Although Fe(III) was inactive with bleomycin and O2, the bleomycin-Fe(III) complex damaged walls and lysed cells in the presence of H2O2. H2O2 causes similar activation of bleomycin-Fe(III) in assays of DNA scission. These results suggest that an activated bleomycin-Fe-O2 complex disrupts essential cell wall polymers in a manner analogous to bleomycin-mediated cleavage of DNA.     

Studies on the chemical reactivity of copper bleomycin

The copper(II) complex of the clinically used antitumor agent bleomycin (Blm) has cytotoxic as well as antitumor properties. To understand the relationship of the bleomycin ligand, copper bleomycin, and other possible metal complexes of this agent, kinetic studies of the formation of Cu(II)Blm, ligand substitution reactions of CuBlm with ethylenediaminetetraaletic acid, and the redox reaction of CuBlm with thiols have been completed and interpreted along with previous studies of the thermodynamic stability of Cu2+ with bleomycin. Cu(II)Bm is found to be kinetically and thermodynamically stable in ligand substitution processes and is only slowly reduced and dissociated by sulfhydryl reagents. The rate constant of reduction of the complex by 2-mercaptoethanol (2-ME) at pH 7.4 and 25 degrees C is 9.5 X 10(-3) M-1 sec-1, explaining the inhibition of Fe2+-dependent strand scission of DNA by Cu2+ in the presence of 2-ME. CuBlm forms in preference to Fe(II)Blm and cannot be reduced and dissociated rapidly enough by thiols to liberate Blm and form the reactive iron complex. In agreement with the observed chemical stability of CuBlm, it is also shown that the complex is stable in human plasma and in the presence of Ehrlich cells suspended in ascites fluid. Interestingly, little CuBlm enters these cells to carry out cytotoxic reactions. Finally, it is shown that both Cu2+ and Zn2+, at equivalent concentrations to Fe2+, effectively inhibit the strand scission of DNA by Fe(II)Blm plus oxygen. However, at substoichiometric amounts of Cu2+, the ferroxidase activity of Blm enables the drug to remain effective in the strand-scission reaction, despite the lowered Cu-free Blm/Fe2+ ratio. These results are discussed in light of the proposed mechanism of action of bleomycin.     

Fe(II) oxidation and Fe(III) incorporation by the M(r) 66,000 microsomal iron protein that stimulates NADPH oxidation.

In a previous study (Minotti, G., and Ikeda-Saito, M. (1991) J. Biol. Chem. 266, 20011-20017) we demonstrated the existence of a M(r) 66,000 microsomal iron protein (MIP) which stimulates NADPH oxidation by shunting electrons from NADPH-cytochrome P-450 reducase to its bound Fe(III). In the present study, purified MIP was depleted of iron and the apoMIP was examined for its ability to incorporate Fe(III) upon an incubation with Fe(II). It was found that apoMIP had an oxygen-dependent ferroxidase activity coupled with the incorporation of Fe(III). The reconstituted MIP exhibited a Fe(III) content and an NADPH oxidation activity similar to those of native MIP. However, the reconstitution of MIP from apoMIP and Fe(II) had to be performed in the presence of detergents to prevent the formation of protein aggregates and the oxidative incorporation of an iron which could not react with NADPH-cytochrome P-450 reductase. This redox inactive iron was probably bound nonspecifically to artifactual sites formed by the protein aggregates.     

Cytotoxicity and site-specific DNA damage induced by nitroxyl anion (NO(-)) in the presence of hydrogen peroxide. Implications for various pathophysiological conditions.

Nitroxyl anion (NO(-)), the one-electron reduction product of nitric oxide (NO(.)), is formed under various physiological conditions. We have used four different assays (DNA strand breakage, 8-oxo-deoxyguanosine formation in calf thymus DNA, malondialdehyde generation from 2'-deoxyribose, and analysis of site-specific DNA damage using (32)P-5'-end-labeled DNA fragments of the human p53 tumor suppressor gene and the c-Ha-ras-1 protooncogene) to study the effects of NO(-) generated from Angeli's salt on DNA damage. It was found that strong oxidants are generated from NO(-), especially in the presence of H(2)O(2) plus Fe(III)-EDTA or Cu(II). NO(.) released from diethylamine-NONOate had no such effect. Distinct effects of hydroxyl radical (HO(.)) scavengers and patterns of site-specific DNA cleavage caused by Angeli's salt alone or by Angeli's salt, H(2)O(2) plus metal ion suggest that NO(-) acts as a reductant to catalyze the formation of the HO(.) from H(2)O(2) plus Fe(III) and formation of Cu(I)-peroxide complexes with a reactivity similar to HO(.) from H(2)O(2) and Cu(II). Angeli's salt and H(2)O(2) exerted synergistically cytotoxic effects to MCF-7 cells, determined by lactate dehydrogenase release assay. Thus NO(-) may play an important role in the etiology of various pathophysiological conditions such as inflammation and neurodegenerative diseases, especially when H(2)O(2) and transition metallic ions are present.