Reaction of Co(II)bleomycin with dioxygen.

The reaction of Co(II)bleomycin with dioxygen has been investigated. Dioxygen binds to the Co(II) complex within the time of mixing according to electron spin resonance and uv-visible spectroscopy and dioxygen analysis. Then, two dioxygenated cobalt centers react, releasing 1 mol of O2 and forming an intermediate characterized by a few highly shifted 1H NMR resonances and loss of the ESR spectrum. This is thought to be a dioxygen-bridged dimer of cobalt bleomycin molecules. Time-dependent absorbance and dioxygen measurements yield the same second order rate constant for this step of the reaction. According to uv-visible and NMR spectral analysis, the intermediate decays into diamagnetic products in a first order rate process. High performance liquid chromatography and 1H NMR studies demonstrate that the product contains two bleomycin species of equal concentration. One component is Co(III)bleomycin, designated Form II. The other is the peroxide adduct of Co(III)bleomycin, Form I, as determined by direct determination of hydrogen peroxide, which is slowly released from the product at low pH. In contrast, hydrogen peroxide is readily detected during the reaction of Co(II)Blm with O2. In isolation, Form I is unstable at pH 7 and is converted within 24 h into a mixture of Form I and Form II.     

Cobalt-bleomycin-deoxyribonucleic acid system. Evidence of deoxyribonucleic acid bound superoxo and mu-peroxo cobalt-bleomycin complexes

Co(II) interacts with bleomycin in aqueous solution, in the presence of air, to give a short-lived mononuclear superoxo Co(III) complex (I). Then, two molecules of complex I react together, with the loss of oxygen, to yield the dinuclear mu-peroxo Co(III) complex (II); the dimerization follows a second-order rate law with k2 = 200 +/- 50 M-1 s-1 at 25 degrees C. The rate of dimerization is lowered by a factor of 2000 when DNA is present at a molar ratio of [nucleotide]/[Co] higher than 16. These results and studies of circular dichroism and electron paramagnetic resonance spectra of complexes strongly suggest the binding of the superoxo complex to DNA (I') as well as that of the mu-peroxo complex (II'); the binding of 1 molecule of complex II for every 2.9 base pairs in DNA has been determined with an apparent equilibrium constant of 8.4 x 10(4) M-1.     

Kinetics of reaction of DNA-bound Fe(III)bleomycin with ascorbate: interplay of specific and non-specific binding

The aerobic redox reaction of Fe(III)bleomycin (Blm) and ascorbate was examined in the absence of DNA and in the presence of 7.5 and 25 calf thymus DNA base pairs per-drug molecule, in order to investigate the effect of DNA binding on the properties of FeBlm activation and DNA strand cleavage. Under these successive conditions, the rate of initial reduction of Fe(III)Blm became progressively slower and biphasic. Using 7.5 base pairs per-molecule of FeBlm, 2-3 times as much drug reacted in the faster step as with the larger DNA to drug ratio. In each case, the more rapid process was identified with the reaction of high spin Fe(III)Blm-DNA. With the smaller ratio, dioxygen consumption, formation of HO(2)-Fe(III)Blm-DNA, and production of DNA strand breaks as measured by the formation of base propenal were largely rate limited by the initial reaction of ascorbate with Fe(III)Blm-DNA. After a burst of reaction with the larger ratio of base pairs to Fe(III)Blm, a small fraction of the total Fe(III)Blm, representing high spin Fe(III)Blm, entered a steady state as HO(2)-Fe(III)Blm-DNA. Thereafter, reaction of dioxygen and base propenal formation occurred slowly with similar first-order rate kinetics. In order to explain these results, it is hypothesized that the metal domain-linker of Fe(III)Blm adopts two conformations with respect to DNA. One, at specific binding sites, is relatively unreactive with ascorbate. The other, present at non-specific sites as HPO(4)-Fe(III)Blm, is readily reactive with ascorbate to generate HO(2)-Fe(III)Blm-DNA. At the larger base pair to drug ratio, movement of Fe(III)Blm between specific and non-specific sites to generate HO(2)-Fe(III)Blm is a necessary part of the mechanism of strand scission.     

Activated bleomycin. A transient complex of drug, iron, and oxygen that degrades DNA

"Activated bleomycin" is an oxygenated iron drug complex which embodies the drug's DNA-cleaving activity. This activity is exercised on DNA, if present, but if DNA is absent, the drug itself is inactivated. Hyperfine interactions in the EPR spectra of activated bleomycin prepared with 57Fe(II) and 17O2 demonstrate the presence of iron as Fe(III) and of bound oxygen originating in dioxygen. Bleomycin can also be activated with Fe(III) and either H2O2 or ethyl hydroperoxide. These latter reactions do not produce a ferrous intermediate nor do they require O2. But O2 is required for the reaction of activated bleomycin with DNA to yield the malondialdehyde-like chromogens used to monitor DNA degradation. The attack on DNA is quantitatively concurrent with the decay of activated bleomycin, however generated.     

Effect of chelating agents and metal ions on the degradation of DNA by bleomycin.

The degradation of DNA by bleomycin was studied in the absence and in the presence of added reducing agents, including 2-mercaptoethanol, dithiothreitol, reduced nicotinamide adenine dinucleotide phosphate, H2O2, and ascorbate, and in the presence of a superoxide anion generating system consisting of xanthine oxidase and hypoxanthine. In all cases, breakage of DNA was inhibited by low concentrations of chelators; where examined in detail, deferoxamine mesylate was considerably more potent than (ethylenedinitrilo)tetraacetic acid. Iron was found to be present in significant quantities in all reaction mixtures. Thus, the pattern of inhibition observed is attributed to the involvement of contaminating iron in the degradation of DNA by bleomycin. Cu(II), Zn(II), and Co(II) inhibit degradation of DNA by bleomycin and Fe(II) in the absence of added reducing agents. A model is proposed in which the degradation of DNA in these systems is dependent on the oxidation of an Fe(II)-bleomycin-DNA complex.     

Deglyco-peplomycin metal complexes on DNA fibers: a role of the sugar moiety for the stability and the orientation of the complexes

Binding structures of metal complexes of deglyco-peplomycin (dPEP) on DNA were investigated by comparing dPEP complexes with those of bleomycin (BLM) using DNA fiber EPR spectroscopy. A low spin species of Fe(III)dPEP observed in the DNA pellet changed irreversibly to several high spin species after the fabrication of the DNA fibers. The g values of the high spin species were different from those of Fe(III)BLM. The high spin species could not be nitrosylated reductively to ON-Fe(II)dPEP, suggesting that some nitrogen atoms coordinated to the Fe(III) were displaced on the DNA fibers. On the other hand, O(2)-Co(II)dPEP remained intact on the fibers similarly to O(2)-Co(II)BLM but with an increased randomness in the orientation on the DNA. In contrast to Cu(II)BLM, a considerable amount of Cu(II)dPEP bound almost randomly on B-form DNA fibers. These results indicated that the sugar moiety in peplomycin or bleomycin is playing an important role in enhancing the stability of the metal-binding domain and in the stereospecificity of the binding on DNA.     

Kinetic analysis of steps in the repair of damaged DNA by human O6-alkylguanine-DNA alkyltransferase

Rates of individual steps in the removal of alkyl groups from O6-methyl (Me) and -benzyl (Bz) guanine in oligonucleotides by human O6-alkylguanine DNA alkyltransferase (AGT) were estimated using rapid reaction kinetic methods. The overall reaction yields hyperbolic plots of rate versus AGT concentration for O6-MeG but linear plots for the O6-BzG reaction, which is approximately 100-fold faster. The binding of AGT and DNA (double-stranded 30-mer/36-mer complex) appears to be diffusion-limited. The rate of dissociation of the complex is approximately 25-fold slower (approximately 1 s(-1)) for DNA containing O6-MeG or O6-BzG than unmodified DNA. The fluorescent dC-analog 6-methylpyrrolo[2,3-d]pyrimidine-2(3H) one deoxyribonucleoside (pyrrolo dC), which pairs with G, was positioned opposite G, O6-MeG, or O6-BzG and used as a probe of the rate of base flipping. A rapid increase of fluorescence (k approximately 200 s(-1)) was observed with O6-MeG and O6-BzG and AGT but not with a Gly mutation at Arg128, which has been implicated in base flipping with crystal structures. Only weak and slower fluorescence changes were observed with G:pyrrolo dC or T:2-aminopurine pairs. These rate estimates were used in a kinetic model in which AGT binds and scans DNA rapidly, flips O6-alkylG residues, transfers the alkyl group in a chemical step that is rate-limiting in the case of O6-MeG but not O6-BzG, and releases the dealkylated DNA. The results explain the overall patterns of rates of alkyl group removal versus AGT concentration and the effects of the mutations, as well as the greater affinity of AGT for DNA with O6-alkylG lesions.     

DNA-binding and oxidative properties of cationic phthalocyanines and their dimeric complexes with anionic phthalocyanines covalently linked to oligonucleotides

Design of chemically modified oligonucleotides for regulation of gene expression has attracted considerable attention over the past decades. One actively pursued approach involves antisense or antigene oligonucleotide constructs carrying reactive groups, many of these based on transition metal complexes. The complexes of Fe(II) and Co(II) with phthalocyanines are extremely good catalysts of oxidation of organic compounds with molecular oxygen and hydrogen peroxide. The binding of positively charged Fe(II) and Co(II) phthalocyanines with single- and double-stranded DNA was investigated. It was shown that these phthalocyanines interact with nucleic acids through an outside binding mode. The site-directed modification of single-stranded DNA by O2 and H2O2 in the presence of dimeric complexes of negatively and positively charged Fe(II) and Co(II) phthalocyanines was investigated. These complexes were formed directly on single-stranded DNA through interaction between negatively charged phthalocyanine in conjugate and positively charged phthalocyanine in solution. The resulting oppositely charged phthalocyanine complexes showed significant increase of catalytic activity compared with monomeric forms of phthalocyanines Fe(II) and Co(II). These complexes catalyzed the DNA oxidation with high efficacy and led to direct DNA strand cleavage. It was determined that oxidation of DNA by molecular oxygen catalyzed by complex of Fe(II)-phthalocyanines proceeds with higher rate than in the case of Co(II)-phthalocyanines but the latter led to a greater extent of target DNA modification.     

Synthetic analogues and biosynthetic intermediates of bleomycin. Metal-binding, dioxygen interaction, and implication for the role of functional groups in bleomycin action mechanism

In order to clarify the role of bleomycin functional groups in action mechanism, the metal-binding, dioxygen activation, and DNA cleavage of several synthetic analogues and biosynthetic intermediates of bleomycin have been investigated. The present results support that 1) the beta-aminoalaninepyrimidine-beta-hydroxyhistidine portion of the bleomycin molecule substantially participates in the Fe(II) and dioxygen interactions, 2) the transposition of the pyrimidine (or pyridine) and imidazole groups in the Fe(II)-coordination is essential for the effective binding and activation of molecular oxygen by the bleomycin ligands, and 3) the gulose-mannose moiety plays an important role as an environmental factor for the efficient dioxygen reduction and DNA cleavage, although the sugar portion does not contribute significantly to the nucleotide specificity in the DNA strand scission. Certain oligopeptides are able to mimic the metal-binding and dioxygen activation by bleomycin, but not induce the effective DNA cleavage. Probably, the bithiazole DNA interaction site of bleomycin delivers the iron/dioxygen chemistry to particularly the DNA (formula, see text) nucleotide sequences.     

Structures of HO(2)-Co(III)bleomycin A(2) bound to d(GAGCTC)(2) and d(GGAAGCTTCC)(2): structure-reactivity relationships of Co and Fe bleomycins

HO(2)-Co(III)bleomycin is a model for HO(2)-Fe(III)bleomycin, which initiates single and double strand cleavage of DNA. In order to enlarge the understanding of its structure and reactivity, three-dimensional structures of HO(2)-Co(III)bleomycin bound to two DNA oligomers, d(GAGCTC)(2) (I) and d(GGAAGCTTCC)(2) (II), that have 5'-GC-3' binding sites, have been determined by nuclear magnetic resonance (NMR) methods. Besides previously recognized determinants of binding selectivity, a probable hydrogen bond was detected between the pyrimidinyl acetamido NH(2) and the carbonyl of cytosine base paired to G at the recognition site. Another hydrogen bond between the NH of the dimethylsulfonium R group and N7 of guanine opposite cytosine at the GC site may contribute to specification of the pyrimidine. Substitution of G with inosine shifted HO(2)-Co(III)Blm A(2)[bond]I and Fe(III)Blm[bond]I into fast exchange on the NMR time scale, supporting the role of the 2-amino group in site specification for each molecule. The conformationally stable metal-domain linker established a close-packed adduct with the minor groove in which the hydroperoxide ligand occupies a sterically constrained pocket that is isolated from the solvent. The hydroperoxide group is directed toward one of the two cytosine H4' hydrogens but is sterically blocked from access to the other by the drug. These findings enlarge the structural understanding of selective binding of Co(III)/Fe(III)Blm species at G-pyrimidine sites. They also rationalize the instability of a number of ligands bound to Co(III)/Fe(III)Blm at specific binding sequences and the relative unreactivity of Fe(III)Blm[bond]I with ascorbate as well as its lack of interaction with spin labels.     

Oxidative strand scission of nucleic acids by a multinuclear copper(II) complex

The compound [Cu(2)(II)(D(1))(H(2)O)(2)](ClO(4))(4).2H(2)O [D(1)=binucleating ligand with tris(2-pyridylmethyl)amine (TMPA) moieties linked in the 5-pyridyl position by a -CH(2)CH(2)- bridge] mediated efficient oxidative cleavage of pBR322 plasmid DNA under reducing conditions. A mononuclear analogue, [Cu(TMPA)(H(2)O)](ClO(4))(2), was less effective at linearizing supercoiled (Form I) plasmid DNA as compared to the binuclear complex. A new method for quenching the copper-dependent reactions has been developed to avoid plasmid scission by the binuclear complex and the standard gel loading buffer. EDTA was not sufficient for retarding copper reaction, but diethyldithiocarbamic acid was capable of inhibiting all reactivity. Investigation of oxidative cleavage of double-helical oligonucleotides by [Cu(2)(II)(D(1))(H(2)O)(2)](ClO(4))(4) confirmed the enhanced reactivity of the binuclear over the mononuclear complex and provided mechanistic insights into the nature of the reaction. Cleavage of DNA required both the binuclear complex and a reductant and likely proceeded through an O(2)-derived intermediate that does not include a diffusible hydroxyl radical. The greater efficiency of the binuclear complex relative to the mononuclear analogue is consistent with their relative abilities to activate dioxygen.     

Effects of O2 on the reactions of activated bleomycin

The antitumor drug, bleomycin, interacts with either Fe(II) and O 2 or Fe(III) and H2O2 to form an activated complex which attacks DNA. Under aerobic conditions, both reactions yield similar quantities of free bases and products consisting of base plus deoxyribose carbon atoms 1 to 3. Under anaerobic conditions, activated bleomycin releases only free base. The yield of free base is the same under aerobic or anaerobic conditions, provided DNA is furnished in excess. When the DNA concentration is limiting, more base is released under anaerobic than under aerobic conditions. Drug self-destruction proceeds as quickly and completely in the presence or absence of O2.     

Reaction of ferrous cytochrome c peroxidase with dioxygen: site-directed mutagenesis provides evidence for rapid reduction of dioxygen by intramolecular electron transfer from the compound I radical site.

The reaction of dioxygen with the ferrous forms of the cloned cytochrome c peroxidase [CCP(MI)] and mutants of CCP(MI) prepared by site-directed mutagenesis was studied by photolysis of the respective ferrous-CO complexes in the presence of dioxygen. Reaction of ferrous CCP(MI) with dioxygen transiently formed a FeII-O2 complex (bimolecular rate constant = (3.8 +/- 0.3) x 10(4) M-1 s-1 at pH 6.0; 23 degrees C) that reacted further (first-order rate constant = 4 +/- 1 s-1) to form a product with an absorption spectrum and an EPR radical signal at g = 2.00 that were identical to those of compound I formed by the reaction of CCP(MI)III with peroxide. Thus, the product of the reaction of CCP(MI)II with dioxygen retained three of the four oxidizing equivalents of dioxygen. Gel electrophoresis of the CCP(MI)II + dioxygen reaction products showed that covalent dimeric and trimeric forms of CCP(MI) were produced by the reaction of CCP(MI)II with dioxygen. Photolysis of the CCP(MI)II-CO complex in the presence of ferrous cytochrome c prevented the appearance of the cross-linked forms and resulted in the oxidation of 3 mol of cytochrome c/mol of CCP(MI)II-CO added. The results provide evidence that reaction of CCP(MI)II with dioxygen causes transient oxidation of the enzyme by 1 equiv above the normal compound I oxidation state. Mutations that eliminate the broad EPR signal at g = 2.00 characteristic of the compound I radical also prevented the rapid oxidation of the ferrous enzyme by dioxygen.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of CO2 in cobalt-catalyzed peroxidations

Augmentation, by CO(2)/HCO(3)(-), of Co(II)-catalyzed peroxidations was explored to clarify whether the rate enhancement was due to CO(2) or to HCO(3)(-). The rate of oxidation of NADH by Co(II) plus H(2)O(2), in Tris or phosphate, was markedly enhanced by CO(2)/HCO(3)(-). Phosphate was seen to inhibit the Co(II)-catalyzed peroxidation, probably due to its sequestration of the Co(II). When CO(2) was used, there was an initial burst of NADH oxidation followed by a slower linear rate. The presence of carbonic anhydrase eliminated this initial burst; establishing that CO(2) rather than HCO(3)(-) was the species responsible for the observed rate enhancements. Both kinetic and spectral data indicated that Co(II) was converted by H(2)O(2) into a less active form from which Co(II) could be regenerated. This less active form absorbed in both the UV and visible regions, and is assumed to be a peroxy bridged binuclear complex. The rate of formation of this absorbing form was increased by HCO(3)(-)/CO(2). A minimal mechanism consistent with these observations is proposed.     

Reaction of nitric oxide with iron bleomycin bound to DNA: properties of the nitrosyl adduct and its reaction with O2

During the ESR spectroscopic titration of nitrosyl-iron bleomycin, ON---Fe(II)Blm, with DNA, its metal domain undergoes a change in environment as the DNA base pair to drug ratio increases to 50 to 1. The ¹⁵N---O stretching frequency of ON---Fe(II)Blm occurs at 1589 cm⁻¹, similar to that for nitrosyl hemoglobin and myoglobin. Upon addition of DNA (3 base pairs per drug molecule), this vibration is substantially broadened. Injection of O₂ into a solution of ON---Fe(II)BlmDNA converts the ESR signal of the nitrosyl species to low spin Fe(III) BlmDNA. NO is largely oxidized to NO₂⁻. The combination of these products suggests that the initial reaction of ON---Fe(II)Blm with O₂ generates Fe(III)Blm and peroxynitrite, O₂NO⁻. If peroxynitrite is formed in the reaction, it does not cause detectable DNA damage. The structural integrity of a supercoiled DNA plasmid, pBR322, is not compromised and no base propenals are produced during this reaction.     

Comparative binding properties of metallobleomycins with DNA 10-mers.

Properties of the interaction of bleomycin (Blm) and metallobleomycins [M = Zn, Cu(II), Fe(III), and HO(2)-Co(III)] with site-specific and nonspecific DNA oligomers, d(GGAAGCTTCC)(2) (I) and d(GGAAATTTCC)(2) (II), respectively, were investigated. With both 10-mers association constants increased in the series Blm A(2), ZnBlm A(2), Cu(II)Blm A(2), Fe(III)Blm A(2), and HO(2)-Co(III)Blm A(2). Generally, the metallobleomycins were bound with a modestly higher affinity to I. One-dimensional (1)H NMR spectra of the imino proton region of I in the presence of this series of compounds revealed that Blm and Zn- and CuBlm bind in fast exchange on the NMR time scale, while the Fe and Co complexes bind in slow exchange. Blm, ZnBlm, and Cu(II)Blm caused little perturbation of the UV circular dichroism spectrum of I or II. In contrast, Fe(III)Blm and HO(2)-Co(III)Blm induced hypochromic effects in the CD spectrum of I and altered the spectrum of II to a smaller extent. On the basis of these results, the DNA binding structures and properties of Blm A(2), ZnBlm A(2), and CuBlm A(2) differ substantially from those of Fe(III)Blm A(2) and HO(2)-Co(III)Blm A(2).     

Spin-trapping studies of the oxidation-reduction reactions of iron bleomycin in the presence of thiols and buffer.

The reaction of ferrous bleomycin with dioxygen is reexamined to clarify whether radical species derived from molecular oxygen are generated. Detection of low levels of spin-trapped oxyradicals confirm the production of OH during this reaction when bleomycin is present in excess, but not when iron and drug concentrations are equal. In phosphate buffer, hydroxyl radicals continue to be spin trapped for at least 15 min after Fe(II)bleomycin has been oxidized to Fe(III)bleomycin. In HEPES buffer, detection of a HEPES radical in the absence of spin trap over the same period independently supports the conclusion that reactive radicals are present after the initial oxidation of Fe(II)bleomycin is complete. When glutathione is included in the aerobic reaction mixture, thiyl radical species are spin trapped. The reaction of Fe(III)bleomycin with cysteine produces thiyl radical without spin-trapped hydroxyl radical.     

A biphasic nature of the bleomycin-mediated degradation of DNA

The bleomycin-mediated digestion of DNA in the presence of ferrous ion, molecular oxygen, and dithiothreitol is characterized by a fast initial reaction, which is followed by a much slower process. The fast degradation is due to the fast activation of the bleomycin-Fe(II) complex and the subsequent fast reaction of the activated complex with DNA. The rate determining step for the slow process is reactivation of the bleomycin-Fe(III) complex. The apparent rate constants for both reactions increase with increasing ionic strength. The latter, unusual results are interpreted in terms of inhibition of bleomycin turnover by binding of cationic species with DNA at low ionic strength.     

Five-coordinated metal complexes of bis(2-hydroxy-1-naphthylideneimine-3-propyl)amine and their reactivity towards dioxygen. Part I. An electrochemical investigation on manganese(II), iron(II), cobalt(II), nickel(II) and copper(II) complexes

The electrochemical behaviour in aprotic solvent of the complexes {M[bis-(2-hydroxy-l-naphthylideneimine-3-propyl)amine]}, where M = Mn(II), Co(II), Fe(II), Ni(II) and Cu(II) is reported. The complexes were prepared and characterized by elemental analysis, infrared and visible spectroscopy and magnetic susceptibility measurements. In addition the reactivity towards dioxygen of the Mn(II), Fe(II) and Co(II) derivatives was investigated, mainly by cyclic voltammetry and gas-volumetric uptake measurements. The results indicate that the Co(II) complexes are able to add dioxygen reversibly, while Mn(II) and Fe(II) compounds undergo an irreversible oxygenation process. The pathway of the dioxygenation processes is tentatively interpreted on the basis of the electrochemical responses. The results confirm that the location of the oxidation potential allows one to predict whether a compound is able to react with dioxygen, but it is not sufficient to predict whether the dioxygenation reaction proceeds reversibly.     

Chemical properties of water-soluble porphyrins. 4. The reaction of a 'picket-fence-like' iron (III) complex with the superoxide oxygen couple

Solution properties of the iron-(III) 'picket-fence-like' porphyrin, Fe(III)-alpha,alpha,alpha, beta-tetra-ortho (N-methyl-isonicotinamidophenyl) porphyrin, (Fe(III)PFP) were investigated. These were acid/base properties of the aquo complex with pKa of 3.9 and its aggregation (formation of dimer with K = 1 X 10(-10) dm3 mol-1), complex formation with cyanide ions and 1-methyl imidazole (1-MeIm), spectral properties of the three iron complexes in their ferric and ferrous form and the one-electron reduction potential of these complexes. Knowing these properties, the reaction of the ferric complexes, aquo, dicyano and bis (1-MeIm), with the superoxide radical and other reducing radicals were studied using the pulse radiolysis technique. The second-order reaction rate constant of O2- with the iron (III) aquo complex which governs the catalytic efficiency of the metalloporphyrin upon the disproportionation of the superoxide radical was 7.6 X 10(7) dm3 mol-1 s-1, two orders of magnitude faster when compared to the reaction of each of the other complexes. The reduction by other radicals with all iron (III) complexes had similar second-order rate constants (10(9) to 10(10) dm3 mol-1 s-1). The reduction reaction in all cases produced Fe(II)PEP and no intermediate was found. The oxidation reaction of Fe(II)PEP by O2- was one order of magnitude faster when compared to the reduction of Fe(III)PFP by the same radical. Since the reactivity of O2- toward the three iron (III) porphyrin complexes follows their reduction potentials, it is suggesting the formation of a peroxo Fe(II) porphyrin as an intermediate. The reactions of the Fe(II)PFP complexes with dioxygen were also studied. The aquo complex was found to be first order in O2 and second order in Fe(II)PFP, suggesting the formation of a peroxo Fe(II) porphyrin as an intermediate. The intermediate formation was corroborated by evidence of the rapid CO binding reaction to the aquo complex of Fe(II)PFP. The two other complexes reacted very slowly with O2 as well as with CO.