Direct hydrogen-atom abstraction by activated bleomycin: an experimental and computational study

Bleomycin (BLM), a glycopeptide antibiotic chemotherapy agent, is capable of single- and double-strand DNA damage. Activated bleomycin (ABLM), a low-spin Fe(III)-OOH complex, is the last intermediate detected prior to DNA cleavage following hydrogen-atom abstraction from the C-4' of a deoxyribose sugar moiety. The mechanism of this C-H bond cleavage reaction and the nature of the active oxidizing species are still open issues. We have used kinetic measurements in combination with density functional calculations to study the reactivity of ABLM and the mechanism of the initial attack on DNA. Circular dichroism spectroscopy was used to directly monitor the kinetics of the ABLM reaction. These experiments yield a deuterium isotope effect, kH/kD approximately 3 for ABLM decay, indicating the involvement of a hydrogen atom in the rate-determining step. H-atom donors with relatively weak X-H bonds accelerate the reaction rate, establishing that ABLM is capable of hydrogen-atom abstraction. Density functional calculations were used to evaluate the two-dimensional potential energy surface for the direct hydrogen-atom abstraction reaction of the deoxyribose 4'-H by ABLM. The calculations confirm that ABLM is thermodynamically and kinetically competent for H-atom abstraction. The activation and reaction energies for this pathway are favored over both homolytic and heterolytic O-O bond cleavage. Direct H-atom abstraction by ABLM would generate a reactive Fe(IV)=O species, which would be capable of a second DNA strand cleavage, as observed in vivo. This study provides experimental and theoretical evidence for direct H-atom abstraction by ABLM and proposes an attractive mechanism for the role of ABLM in double-strand cleavage.     

Proton-shuffle mechanism of O-O activation for formation of a high-valent oxo-iron species of bleomycin

Bleomycins (BLMs) can utilize H2O2 to cleave DNA in the presence of ferric ions. DFT calculations were used to study the mechanism of O-O bond cleavage in the low-spin FeIII-hydroperoxo complex of BLM. The following alternative hypotheses were investigated using realistic structural models: (a) heterolytic cleavage of the O-O bond, generating a Compound I (Cpd I) like intermediate, formally BLM-FeV=O; (b) homolytic O-O cleavage, leading to a BLM-FeIV=O species and an OH* radical; and (c) a direct O-O cleavage/H-abstraction mechanism by ABLM. The calculations showed that (a) is a facile and viable mechanism; it involves acid-base proton reshuffle mediated by the side-chain linkers of BLM, causing thereby heterolytic cleavage of the O-O bond and generation of Cpd I. Formation of Cpd I is found to involve a barrier of 13.3 kcal/mol, which is lower than the barriers in the alternative mechanisms (b and c) that possess respective barriers of 31 and 17 kcal/mol. The so-formed Cpd I species with a radical on the side-chain linker, methylvalerate (V), adjacent to the BLM-FeIV=O complex, resembles the formation of the active species of cytochrome c peroxidase in the Poulos-Kraut proton-shuffle mechanism in heme peroxidases (Poulos, T. L.; Kraut, J. J. Biol. Chem. 1980, 255, 8199-8205). Experimental data are discussed and shown to be in accord with this proposal. It suggests that the high-valence Cpd I species of BLM participates in the DNA cleavage. This is an alternative mechanistic hypothesis to the exclusive reactivity scenario based on ABLM (FeIII-OOH).     

Characterization of bleomycin cleavage sites in strongly bound hairpin DNAs

The first complete, systematic study of DNA degradation by bleomycin under conditions analogous to those likely in a therapeutic setting has been carried out. Hairpin DNAs selected for their ability to bind strongly to BLM A(5) were used to determine the relationship between high-affinity DNA binding sites and the cleavage efficiency and selectivity of BLM A(5) and deglycoBLM A(5) on these DNAs. Of the 10 hairpin DNAs examined, 8 contained at least one 5'-GC-3' or 5'-GT-3' cleavage site, which have traditionally been associated with strong cleavage by Fe·BLM. In the hairpin DNAs, these included the strongest cleavage sites for BLM A(5) and were generally among those for deglycoBLM A(5). However, numerous additional cleavages were noted, many at sequences not usually associated with (deglyco)BLM-mediated cleavage. The remaining DNAs lacked the preferred (5'-GC-3' or 5'-GT-3') BLM cleavage sequences; however, strong cleavage was nonetheless observed at a number of unusual cleavage sites. The most prominent cleavage sequences were 5'-AT-3', 5'-AA-3', 5'-GA-3', and 5'-TT-3'; treatment with Fe(II)·BLM A(5) or Fe(II)·deglycoBLM A(5) resulted in strong cleavage at these sequences. Additionally, in contrast with BLM A(5), which produced cleavage within the randomized and flanking invariant regions, deglycoBLM A(5) showed a preference for cleavage in the randomized region of the DNAs. Previous reports have established that deglycoBLM exhibits decreased DNA cleavage efficiency relative to BLM. This was also generally observed when comparing cleavage efficiencies for the strongly bound hairpin DNAs. However, some cleavage bands produced by Fe·deglycoBLM A(5) were stronger in intensity than those produced by BLM A(5) at concentrations optimal for both compounds. To investigate the chemistry of DNA degradation, selected hairpin DNAs were treated with n-butylamine following cleavage with Fe(II)·BLM A(5) or Fe(II)·deglycoBLM A(5) to explore the alkali labile pathway of DNA degradation by BLM. While all 10 DNAs showed evidence of alkali labile products, five DNA hairpins afforded some products formed solely via the alkali labile pathway.     

Electronic structure and reactivity of low-spin Fe(III)-hydroperoxo complexes: comparison to activated bleomycin

The spectroscopic properties, electronic structure, and reactivity of the low-spin Fe(III)-hydroperoxo complex [Fe(N4Py)(OOH)](2+) (1, N4Py = N,N-bis(2-pyridylmethyl)-N-bis(2-pyridyl)methylamine) are investigated in comparison to those of activated bleomycin (ABLM). Complex 1 is characterized by Raman features at 632 (Fe-O stretch) and 790 cm(-1) (O-O stretch), corresponding to a strong Fe-O bond (force constant 3.62 mdyn/A) and a weak O-O bond (3.05 mdyn/A). The UV-vis spectrum of 1 shows a broad absorption band around 550 nm that is assigned to a charge-transfer transition from the hydroperoxo to a t(2g) d orbital of Fe(III) using resonance Raman and MCD spectroscopies and density functional (DFT) calculations. Compared to low-spin [Fe(TPA)(OH(x))(OO(t)Bu)](x+)(TPA = tris(2-pyridylmethyl)amine, x = 1 or 2), an overall similar Fe-OOR bonding results for low-spin Fe(III)-alkylperoxo and -hydroperoxo species. Correspondingly, both systems show similar reactivities and undergo homolytic cleavage of the O-O bond. From the DFT calculations, this reaction is more endothermic for 1 due to the reduced stabilization of the .OH radical compared to .O(t)Bu and the absence of the hydroxo ligand that helps to stabilize the resulting Fe(IV)=O species. In contrast, ABLM has a somewhat different electronic structure where no pi donor bond between the hydroperoxo ligand and iron(III) is present [Neese, F.; Zaleski, J. M.; Loeb-Zaleski, K.; Solomon, E. I. J. Am. Chem. Soc. 2000, 122, 11703]. Possible reaction pathways for ABLM are discussed in relation to known experimental results.     

Total synthesis of deamido bleomycin a(2), the major catabolite of the antitumor agent bleomycin

Metabolic inactivation of the antitumor antibiotic bleomycin is believed to be mediated exclusively via the action of bleomycin hydrolase, a cysteine proteinase that is widely distributed in nature. While the spectrum of antitumor activity exhibited by the bleomycins is believed to reflect the anatomical distribution of bleomycin hydrolase within the host, little has been done to characterize the product of the putative inactivation at a chemical or biochemical level. The present report describes the synthesis of deamidobleomycin demethyl A(2) (3) and deamido bleomycin A(2) (4), as well as the respective aglycones. These compounds were all accessible via the key intermediate N(alpha)-Boc-N(beta)-[1-amino-3(S)-(4-amino-6-carboxy-5-methylpyrimidin-2-yl)propion-3-yl]-(S)-beta-aminoalanine tert-butyl ester (16). Synthetic deamido bleomycin A(2) was shown to be identical to the product formed by treatment of bleomycin A(2) with human bleomycin hydrolase, as judged by reversed-phase HPLC analysis and (1)H NMR spectroscopy. Deamido bleomycin A(2) was found to retain significant DNA cleavage activity in DNA plasmid relaxation assays and had the same sequence selectivity of DNA cleavage as bleomycin A(2). The most significant alteration of function noted in this study was a reduction in the ability of deamido bleomycin A(2) to mediate double-strand DNA cleavage, relative to that produced by BLM A(2).     

Conformationally constrained analogues of bleomycin A5

The bleomycin (BLM) group antitumor antibiotics are glycopeptide-derived natural products shown to cause sequence selective lesions in DNA. Prior studies have indicated that the linker region, composed of the methylvalerate and threonine residues, may be responsible for a conformational bend in the agent required for efficient DNA cleavage. We have synthesized a number of conformationally constrained methylvalerate analogues and incorporated them into deglycobleomycin A(5) congeners using our recently reported procedure for the solid phase construction of (deglyco)bleomycin and its analogues. These analogues were designed to probe the effects of conformational constraint of the native valerate moiety. Initial experiments indicated that the constrained molecules, none of which mimic the conformation proposed for the natural valerate linker, possessed DNA cleavage activity, albeit with potencies less than that of (deglyco)BLM and lacking sequence selectivity. Further experiments demonstrated that these analogues failed to produce alkali-labile lesions in DNA or sequence selective oxidative damage in RNA. However, two of the conformationally constrained deglycoBLM analogues were shown to mediate RNA cleavage in the absence of added Fe(2+). The ability of the analogues to mediate the oxygenation of small molecules was also assayed, and it was shown that they were as competent in the transfer of oxygen to low molecular weight substrates as the parent compound.     

A novel DNA hairpin substrate for bleomycin

A 16-nucleotide DNA hairpin containing 4-aminobenzo[g]quinazoline-2-one 2'-deoxyribose at position 15 has been prepared and found to lack significant fluorescence. When treated with Fe(II).BLM, the hairpin was found to undergo oxidative transformation selectively at position 15. The predominant fluorescent product was characterized and quantified. The pro-fluorescent DNA hairpin was used as a substrate for 15 bleomycin congeners, and the results were compared with those obtained following cleavage of a radiolabeled DNA duplex and PAGE analysis.     

An efficient mammalian transfer RNA target for bleomycin

The antitumor antibiotic bleomycin has long been believed to exert its therapeutic effects at the level of DNA cleavage. Recently, evidence has been presented to suggest that RNA cleavage may also be important and that one or more transfer RNAs may be involved. To define those tRNAs that may represent important loci for the action of bleomycin, we have fractionated chicken liver tRNAs and identified those isoacceptors most susceptible to oxidative cleavage by Fe(II).BLM. Two chicken liver tRNAs, tRNA3Lys and tRNAPhe, were found to be cleaved with exceptional facility by Fe(II).BLM, and both were cleaved predominantly at U66. The cleavage of tRNA3Lys was shown to be minimally affected by physiological concentrations of Mg2+. Chicken liver tRNA3Lys is identical in sequence with human tRNA3Lys. These findings support a possible role for a critical tRNA such as tRNA3Lys in the mechanism by which bleomycin mediates its antitumor activity.     

Metallobleomycin-mediated cleavage of DNA not involving a threading-intercalation mechanism.

The DNA cleavage properties of metallobleomycins conjugated to three solid supports were investigated using plasmid DNA, relaxed covalently closed circular DNA, and linear duplex DNA as substrates. Cleavage of pBR322 and pSP64 plasmid DNAs by Fe(II).BLM A(5)-CPG-C(2) was observed with efficiencies not dissimilar to that obtained using free Fe(II).BLM A(5). Similar results were observed following Fe(II).BLM A(5)-CPG-C(2)-mediated cleavage of a relaxed plasmid, a substrate that lacks ends or negative supercoiling capable of facilitating strand separation. BLMs covalently tethered to solid supports, including Fe(II).BLM A(5)-Sepharose 4B, Fe(II).BLM A(5)-CPG-C(6), and Fe(II).BLM A(5)-CPG-C(2), cleaved a 5'-(32)P end labeled linear DNA duplex with a sequence selectivity identical to that of free Fe(II).BLM A(5); cleavage predominated at 5'-G(82)T(83)-3' and 5'-G(84)T(85)-3'. To verify that these results could also be obtained using other metallobleomycins, supercoiled plasmid DNA and a linear DNA duplex were employed as substrates for Co(III).BLM A(5)-CPG-C(2). Free green Co(III).BLM A(5) was only about 2-fold more efficient than green Co(III).BLM A(5)-CPG-C(2) in effecting DNA cleavage. A similar result was obtained using Cu(II).BLM A(5)-CPG-C(2) + dithiothreitol. In addition, the conjugated Co.BLM A(5) and Cu.BLM A(5) cleaved the linear duplex DNA with a sequence selectivity identical to that of the respective free metalloBLMs. Interestingly, when supercoiled plasmid DNA was used as a substrate, conjugated Fe.BLM A(5) and Co.BLM A(5) were both found to produce Form III DNA in addition to Form II DNA. The formation of Form III DNA by conjugated Fe.BLM A(5) was assessed quantitatively. When corrected for differences in the intrinsic efficiencies of DNA cleavage by conjugated vs free BLMs, conjugated Fe.BLM A(5) was found to produce Form III DNA to about the same extent as the respective free Fe.BLM A(5), arguing that this conjugated BLM can also effect double-strand cleavage of DNA. Although previous evidence supporting DNA intercalation by some metallobleomycins is convincing, the present evidence indicates that threading intercalation is not a requirement for DNA cleavage by Fe(II).BLM A(5), Co(III).BLM A(5), or Cu(I).BLM A(5).     

Resonance Raman studies of HOO-Co(III)bleomycin and Co(III)bleomycin: identification of two important vibrational modes, nu(Co-OOH) and nu(O-OH)

Bleomycin is an antitumor agent whose cytotoxicity is dependent on its ability to bind DNA in the nucleus and effect double-stranded DNA cleavage, which is difficult for the cell to repair. In order for this DNA cleavage to occur, bleomycin must, through a series of reactions, form a low-spin Fe(III) complex, the putative "activated" form of the drug, HOO-Fe(III)bleomycin. The relative strengths of the bonds in the Fe(III)-OOH linkage have not been determined due to the weakness of the hydroperoxo-to-iron(III) charge-transfer transition. The much more stable HOO-Co(III)bleomycin has often been studied as a structural analogue of HOO-Fe(III)bleomycin, and hence, an understanding of the relative bond strengths in the Co-OOH linkage may serve to enhance our understanding of the analogous Fe-OOH linkage. In this report, we present resonance Raman data that identify two important vibrational modes in the Co-OOH linkage, the stretching modes, nu(Co-OOH) and nu(O-OH). Both of these vibrational modes were found to be unperturbed by complexation of the drug with calf thymus DNA. Advantage was also taken of the isostructural realtionship between Fe-bleomycin and Co-bleomycin to analyze and assign the high-frequency modes for HOO-Co(III)bleomycin and Co(III)bleomycin (A(2) and B(2)). These data could be useful for future studies of photoactivated Co-bleomycin and Co-bleomycin analogues in an attempt to characterize oxygen-independent DNA damage pathways.     

Conformational/configurational analysis of all the binding geometries of cobalt(III) bleomycin

No crystal structure of metallobleomycin (BLM) exists, and the exact coordination mode of the ligand is unknown. To date, spectroscopic investigations of BLM complexes and crystal structures of BLM models have been used to propose its metal coordination sites. This has led to contradictory interpretations of the metal coordination sphere in BLM. Inorganic molecular mechanics and configurational/conformational searches were used to analyze HOO-CoBLM A2, H2O-CoBLM A2, and HOO-CoPEP with commonly proposed binding geometries. The lowest energy binding geometry found was one with the mannose carbamoyl bound to the cobalt ion. The Monte Carlo dihedral and translational variational searches were able to find most of the configurations available to cobalt(III) bleomycin in the three binding geometries examined.     

Ratiometric fluorescence detection of bleomycin based on proximity-dependent fluorescence conversion of DNA-templated silver nanoclusters

We design a ratiometric fluo rescent sensing platform for bleomycin(BLM) by using proximity-dependent DNA-templated silver nanoclusters(DNA-AgNCs) probe.This ratiometric sensing system is constructed with DNA-AgNCs as single fluorophore.The proposed strategy is based on the two following facts:(1) a covert DNA can approach and transform the DNA-AgNCs with green emission(G-DNA-AgNCs) into red emission through hybridization reaction.(2) The specific cleavage of the convert DNA by BLM in the presence of Fe(Ⅱ) inhibits the discoloration of G-DNA-AgNCs.Thus,benefiting from the specific recognition of BLM and unique properties of G-DNA-AgNCs,a hignly-sensitive ratiometric sensor for BLM has been successfully developed.The detection limit is as low as 30 pmol/L.This label-free fluorescence probe possesses advantages of convenient synthetic process and low cost.Moreover,this ratiometric method has been applied to the detection of BLM in human serum samples,illustrating a promising tool for analysis of BLM in cancer therapy.     

DFT analysis of interligand vibrations in a hydroperoxo complex of cobalt bleomycin

Density functional theory (DFT) has been applied to the analysis of interligand vibrations in two chiral isomers of hydroperoxo complex of cobalt bleomycin (BLM-Co(III)-OOH, BLM = bleomycin). The DFT-based normal coordinate analysis reveals that 16O/18O isotope-sensitive modes associated with the Co-OOH moiety uniquely reflect the chiral organization of ligands around the cobalt atom. This study provides an independent probe of cobalt chirality coordinated to BLM and shows that interligand modes associated with the Co-OOH moiety could be used as a structural marker of the chiral isomers.     

Orientation of iron bleomycin and porphyrin complexes on DNA fibers

Bleomycin (Blm) is an antitumor agent that requires iron and oxygen for strand cleavage of DNA. In this study, ferric bleomycin, Fe(III)Blm, or the nitric oxide adduct of ferrous bleomycin, ON-Fe(II)Blm, were bound to one-dimensionally oriented DNA fibers. Reductive nitrosylation of Fe(III) complexes took place in situ on B-form DNA fibers. Electron paramagnetic resonance (EPR) spectra were obtained as a function of the angle phi between the magnetic field B and the fiber axis Zf. For comparison, EPR spectra were acquired for ON-Fe(II)TMpyP and ON-Fe(II)TMpyP-Im on oriented DNA fibers, where TMpyP is 5,10,15,20-tetrakis(1-methyl-4-pyridino)porphyrin and Im is imidazole. EPR spectra showed both low-spin Fe(III)Blm and ON-Fe(II)Blm bound to B-form DNA in two slightly different binding orientations in the ratio of 1:0.2. With A-form DNA, a fraction of bound Fe(III)Blm was high spin. Specifically, the angle beta between the fiber axis Zf and the g axis, gz, perpendicular to or nearly perpendicular to the equatorial plane of the iron complex was estimated as 20 degrees and 25 degrees for ON-Fe(II)Blm and 30 degrees and 25 degrees for Fe(III)Blm, respectively. The angle gamma that determines the orientation of gx and gy axes was estimated as 90 degrees for the two ON-Fe(II)Blm species and 10 degrees for the two Fe(III)Blm species, respectively. The NO was held rigidly in place as the temperature increased from 123 K to room temperature for ON-Fe(II)Blm but not for ON-Fe(II)TMpyP or ON-Fe(II)TMpyP-Im. It is hypothesized that the NO is structurally oriented by hydrogen bonding like the peroxide is held in HO2(-)-Co(III)Blm (Wu et al. J. Am. Chem. Soc. 1996, 118, 1281-1294). The EPR parameters are consistent with a six-coordinate complex for ON-Fe(II)Blm, although the superhyperfine structure from the trans nitrogen was not detected. The increase in g value anisotropy upon binding ON-Fe(II)Blm to DNA fiber may be caused by an increase in the overlap of d pi and 2p pi* orbitals induced by an interaction of NO with DNA and/or by a perturbation of d orbitals due to the pyrimidine-guanine interaction. It is concluded that the EPR parameters of ON-Fe(II)Blm and Fe(III)Blm bound to oriented DNA support the hypothesis that FeBlm species bind to DNA with adduct structures similar to those formed by related CoBlm species and DNA.     

Quantum mechanical/molecular mechanical study of mechanisms of heme degradation by the enzyme heme oxygenase: the strategic function of the water cluster

Heme degradation by heme oxygenase (HO) enzymes is important in maintaining iron homeostasis and prevention of oxidative stress, etc. In response to mechanistic uncertainties, we performed quantum mechanical/molecular mechanical investigations of the heme hydroxylation by HO, in the native route and with the oxygen surrogate donor H2O2. It is demonstrated that H2O2 cannot be deprotonated to yield Fe(III)OOH, and hence the surrogate reaction starts from the FeHOOH complex. The calculations show that, when starting from either Fe(III)OOH or Fe(III)HOOH, the fully concerted mechanism involving O-O bond breakage and O-C(meso) bond formation is highly disfavored. The low-energy mechanism involves a nonsynchronous, effectively concerted pathway, in which the active species undergoes first O-O bond homolysis followed by a barrier-free (small with Fe(III)HOOH) hydroxyl radical attack on the meso position of the porphyrin. During the reaction of Fe(III)HOOH, formation of the Por+*FeIV=O species, compound I, competes with heme hydroxylation, thereby reducing the efficiency of the surrogate route. All these conclusions are in accord with experimental findings (Chu, G. C.; Katakura, K.; Zhang, X.; Yoshida, T.; Ikeda-Saito, M. J. Biol. Chem. 1999, 274, 21319). The study highlights the role of the water cluster in the distal pocket in creating "function" for the enzyme; this cluster affects the O-O cleavage and the O-Cmeso formation, but more so it is responsible for the orientation of the hydroxyl radical and for the observed alpha-meso regioselectivity of hydroxylation (Ortiz de Montellano, P. R. Acc. Chem. Res. 1998, 31, 543). Differences/similarities with P450 and HRP are discussed.     

Interaction of bleomycin with deoxyribonucleic acid oligomer: proton nuclear magnetic resonance titration study using novel bleomycin complexes with Ni2+ and VO3+.

Two metal complexes of bleomycin (BLM), BLM-Ni2+ and BLM-VO3+ are used for studying interactions between BLM and deoxyribonucleic acid (DNA) by nuclear magnetic resonance. Although these BLMs do not mediate DNA strand scission under the usual conditions, they bind to DNA in the same manner as the active metal complexes of bleomycin (BLM-Fe2+ and BLM-Co3+). A self-complementary dodecanucleotide, d(CCCCAGCTGGGG), having a single site for cleavage was synthesized. d(CCCCAATTGGGG), which contains no -GpC- sequence, was also synthesized. The BLM-metal complexes were shown to bind specifically to the GpC site by circular dichroism and fluorescence titration studies. We assigned all the resonances for imino protons and phosphorus, and most of the nonexchangeable proton resonances of d(CCCCAGCTGGGG). No substantial change in the chemical shifts of these signals was observed upon titration with either BLM-Ni2+ or BLM-VO3+. This result is not consistent with a model of the strong intercalation of the BLMs between the base-pairs. The BLMs bind to DNA in a different manner, and DNA does not change its conformation upon binding with BLMs.     

Catalytic oxidation with a non-heme iron complex that generates a low-spin Fe(III)OOH intermediate

The antitumor drug bleomycin (BLM) is proposed to act via a low-spin iron(III) hydroperoxide intermediate called "activated bleomycin". To gain more insight into the mechanistic aspects of catalytic oxidation by these intermediates we have studied the reactivity of [(N4Py)Fe(CH3CN)](ClO4)2 (1) (N4Py = N,N-bis(2-pyridylmethyl)-N-bis(2-pyridyl)methylamine) with excess H2O2. Under these conditions a transient purple species is generated, [(N4Py)FeOOH]2- (2), which has spectroscopic features and reactivity strongly reminiscent of activated bleomycin. The catalytic oxidation of alkanes such as cyclohexane, cyclooctane, and adamantane by 1 with H2O2 gave the corresponding alcohols and ketones in up to 31% yield. It was concluded, from the O2 sensitivity of the oxidation reactions, the formation of brominated products in the presence of methylene bromide, and the nonstereospecificity of the oxidation of cis- or trans-dimethylcyclohexane, that long-lived alkyl radicals were formed during the oxidations. Oxidation of alkenes did not afford the corresponding epoxides in good yields but resulted instead in allylic oxidation products in the case of cyclohexene, and cleavage of the double bond in the case of styrene. Addition of hydroxyl radical traps, such as benzene and acetone, led to only partial quenching of the reactivity. The kinetic isotope effects for cyclohexanol formation, ranging from 1.5 in acetonitrile to 2.7 in acetone with slow addition of H2O2, suggested the involvement of a more selective oxidizing species in addition to hydroxyl radicals. Monitoring the UV/Vis absorption of 2 during the catalytic reaction showed that 2 was the precursor for the active species. On the basis of these results it is proposed that 2 reacts through homolysis of the O-O bond to afford two reactive radical species: [(N4Py)Fe(IV)O]2+ and *OH. The comparable reactivity of 1 and Fe-BLM raises the possibility that they react through similar mechanistic pathways.     

Alteration of the selectivity of DNA cleavage by a deglycobleomycin analogue containing a trithiazole moiety

The bleomycin (BLM) group of antitumor antibiotics effects DNA cleavage in a sequence-selective manner. Previous studies have indicated that the metal-binding and bithiazole moieties of BLM are both involved in the binding of BLM to DNA. The metal-binding domain is normally the predominant structural element in determining the sequence selectivity of DNA binding, but it has been shown that replacement of the bithiazole moiety with a strong DNA binder can alter the sequence selectivity of DNA binding and cleavage. To further explore the mechanism by which BLM and DNA interact, a trithiazole-containing deglycoBLM analogue was synthesized and tested for its ability to relax supercoiled DNA and cleave linear duplex DNA in a sequence-selective fashion. Also studied was cleavage of a novel RNA substrate. Solid-phase synthesis of the trithiazole deglycoBLM A(5) analogue was achieved using a TentaGel resin containing a Dde linker and elaborated from five key intermediates. The ability of the resulting BLM analogue to relax supercoiled DNA was largely unaffected by introduction of the additional thiazole moiety. Remarkably, while no new sites of DNA cleavage were observed for this analogue, there was a strong preference for cleavage at two 5'-GT-3' sites when a 5'-(32)P end-labeled DNA duplex was used as a substrate. The alteration of sequence selectivity of cleavage was accompanied by some decrease in the potency of DNA cleavage, albeit without a dramatic diminution. In common with BLM, the trithiazole analogue of deglycoBLM A(5) effected both hydrolytic cleavage of RNA in the absence of added metal ion and oxidative cleavage in the presence of Fe(2+) and O(2). In comparison with BLM A(5), the relative efficiencies of hydrolytic cleavage at individual sites were altered.     

Phototransformations of methylsubstituted oxiranes’ radical cations in freonic matrices at 77 K

It has been established that, upon X-ray irradiation of various methyloxiranes in freonic matrices at 77 K, both open and cyclic (with the elongated C-C bond) forms of radical cations are stabilized. It has been shown that observed reversible photoinduced transformations of 2,3-dimethyloxirane and methyloxirane radical cations are related to the conversion between the open and cyclic forms of the radical cations with high quantum yields (0.02?C0.39, depending on the oxirane and the matrix). For the trimethyloxirane radical cation the action of light on the trans-isomer of the open form results in its photoinduced transformation into a C-centered radical with low quantum efficiency (??4 × 10^?3). Tetramethyloxirane radical cations, stabilized in their open form, are resistant to the action of light. Probable causes of the observed effects are discussed. Upon the X-ray irradiation of 2,2-dimethyloxirane in freonic matrices at 77 K, a cyclic form of the radical cation is stabilized (presumably, as part of a complex with matrix molecules) which transforms into a distonic C-centered radical cation under the action of light with the quantum yield of ??10^?3.     

Disproportionation of Iron(III) Porphyrin pi-Cation Radicals in the Presence of Sterically Hindered Pyridines. Spectroscopic Detection of Asymmetric Highly Oxidized Intermediates

The reactivity of iron(III) tetraphenylporphyrin pi-cation radical (TPP(*))Fe(III)(ClO(4))(2), (1-1) iron(III) tetra-p-tolylporphyrin pi-cation radical (TTP(*))Fe(III)(ClO(4))(2) (1-2) and iron(III) tetramesitylporphyrin pi-cation radical (TMP(*))Fe(III)(ClO(4))(2) (1-3) complexes with 2,4,6-collidine, 2,3,6-collidine, 2-picoline, 2,6-di-tert-butylpyridine, and 2,6-dibromopyridine has been examined by (1)H NMR spectroscopy in dichloromethane-d(2) solution at low temperatures. These complexes undergo hydration processes which are essential in the generation of highly oxidized species via acid base/equilibria of coordinated water followed by disproportionation pathway, giving as sole stable products [(TPP(*))Fe(III)OFe(III)(TPP)](+) (4-1), [(TTP(*))Fe(III)OFe(III)(TTP)](+) (4-2), and (TMP)Fe(III)(OH) (6) respectively. The sterically hindered pyridines act as efficient proton scavengers. Two novel highly oxidized iron complexes have been detected by (1)H NMR spectroscopy after addition of 2,4,6-collidine to (TTP(*))Fe(III)(ClO(4))(2) or (TPP(*))Fe(III)(ClO(4))(2) in dichloromethane-d(2) solution at 202 K. New intermediates have been identified as iron porphyrin N-oxide complexes, i.e., iron(III) porphyrin N-oxide cation radical (2-n) and iron(IV) porphyrin N-oxide radical (3-n). The (1)H NMR results indicate that the D(4)(h)() symmetry of the parent iron(III) pi-cation radical is drastically reduced upon disproportionation in the presence of proton scavengers. Both species are very unstable and were observed from 176 to 232 K. The intermediate 2-2 has a (1)H NMR spectrum which demonstrates large hyperfine shifts (ppm) for the meso p-tolyl substituents (ortho 98.0, 94.8, 92.9, 91.7; meta -34.8, -38.7, -41.5, -42.3; p-CH(3) -86.3, -88.0) which are consistent with presence of an N-substituted iron porphyrin radical in the product mixture. The characteristic (1)H NMR spectrum of 2-2 includes six pyrrole resonances at 149.6, 118.2, 115.4, 88.3, 64.6, and 55.7 ppm at 202 K, i.e., in the positions corresponding to iron(III) high-spin porphyrins. On warming to 222 K, the pyrrole resonances broaden and then coalesce pairwaise. Such dynamic behavior is accounted for by a rearrangement mechanism which involves an inversion of the porphyrin puckering. The pattern of p-tolyl resonances revealed the cation radical electronic structure of 3-2. The p-tolyl resonances are divided in two distinct sets showing opposite direction of the isotropic shift for the same ring positions. The pyrrole resonances of 3-2 also demonstrated downfield and upfield shifts. A disproportionation mechanism of the hydrated iron porphyrin cation radicals to generate 2 and 3 has been proposed. Both intermediates react with triphenylphosphine to produce triphenylphosphine oxide and high-spin iron porphyrins. Addition of 2,4,6-collidine to (TMP(*))Fe(III)(ClO(4))(2) does not produce analogs of 2 and 3 found for sterically unprotected porphyrins. It results instead in the formation of a variety of X(TMP(*))Fe(IV)O (5) complexes also accounted for by the disproportionation process.