Radicals of nitroimidazole derivatives: pH dependence of rates of formation and decay related to acid-base equilibria

Three analogous 5-nitroimidazoles, having radiosensitizing and cytotoxic properties, have been studied by pulse-radiolysis in N2O-saturated aqueous formate solutions. Rates of formation of the radicals ImNO2-. are found to have little pH dependence. Decay of the radicals always follows second-order kinetics. The observed rates of decay decrease by three to four orders of magnitude over the pH range 0-12. A pK at 2.3 has been observed kinetically for metronidazole. The pK assigned to the radical couple (ImH)NO2H./(ImH)-NO2-., or alternatively (ImH2+)-NO2-./(ImH)-NO2-., varies from 4.7 to 6.1, depending on the substituents on the imidazole ring. Intrinsic second-order rate constants for decay of the acidic form of the radical, of the anionic form and of the mixed reactions were determined. While the anionic radical reacts slowly with itself, both the acidic radical self-reaction and the mixed reaction proceed at fast rates. The implications of these chemical properties to the mechanisms of radiosensitization and cytotoxicity of the nitroaryl compounds are briefly discussed.     

Abnormal radiosensitizing and cytotoxic properties of ortho-substituted nitroimidazoles

Various 5-substituted 4-nitroimidazoles have been shown to be much more efficient radiosensitizers and much more toxic than would have been predicted from their electron affinities, as measured by values of one-electron reduction potential, E17. Using Chinese hamster V79 cells in vitro, a comparison has been made with some isomeric 4-substituted 5-nitroimidazoles. These compounds have E17 values some 64mV greater than the 4-nitroimidazoles, yet show much lower sensitizing efficiency and also lower toxicity. Neither series of compounds shows the greater toxicity towards hypoxic cells usually associated with nitroaromatic and nitroheterocyclic compounds. The second-order rate constants, k2, for reaction of these isomeric nitroimidazoles with glutathione and dithiothreitol were determined. Within each series the value of k2 increased with increasing electron affinity, however, the 4-nitroimidazoles were always more reactive than their corresponding 5-nitro isomers. The sensitizing and toxic properties of these compounds may involve depletion of intracellular thiols; this possibility is discussed.     

Oxygen inhibition of nitroreductase: electron transfer from nitro radical-anions to oxygen.

The inhibition of many nitroreductases by oxygen has been explained by Mason and Holtzman in terms of electron transfer to oxygen from the nitro radical-anions, which have been identified as the first intermediate in some reductase systems. We have used the pulse radiolysis technique to measure the bimolecular rate constants of this electron-transfer reaction for over 20 nitro compounds, including substituted 2- and 5-nitroimidazoles of interest as antiprotozoal drugs and radiosensitizers, nitrofurans in use as antibacterial agents, and substituted nitrobenzenes previously used as model substrates for nitroreductases. The logarithm of the rate constant for the reaction of the nitro radical-anion with oxygen is linearly related to the one-electron reduction potential of the nitro compound.     

No detectable reaction of the anion radical metabolite of nitrofurans with reduced glutathione or macro-molecules

The initial metabolite formed by most mammalian nitroreductases is the nitro anion free radical. We, as well as others, have proposed that nitroheterocyclic anion radicals covalently bind to protein, DNA, or thiol compounds such as reduced glutathione (GSH). Our results indicate that even at 100 mM GSH does not affect the steady-state concentration of the nitro anion free radical of N-[4-(5-nitro-2-furyl)-2-thiazolyl]acetamide (NFTA) in rat hepatic microsomal or xanthine oxidase incubations. The steady-state ESR amplitude of the anion radical is also unchanged by the addition of BSA or DNA. Similar results are obtained with nitrofurazone and nitrofurantoin. The reactive chemical species which binds to tissue macromolecules and GSH upon the reduction of nitrofurans remains unknown, but the anion free radical metabolite can be excluded from consideration.     

Structure-activity relationships in the development of hypoxic cell radiosensitizers. I. Sensitization efficiency.

The efficiency of 35 nitroaromatic and nitroheterocyclic compounds in radiosensitizing hypoxic Chinese Hamster cells in vitro was determined. The concentration C of the compound required to achieve an enhancement ratio of 1.6 was measured, and the redox and partition properties were quantified as the one-electron reduction potential at pH 7, E, and the octanol: water partition coefficient, P, respectively. Most of the compounds studied were 2-nitroimidazoles, but some 4- and 5-nitromidazoles, 5-nitrofurans and nitrobenzenes were investigated for comparison. Together with data for nine nitroimidazoles previously reported, the results were fitted to a structure-activity relationship of the form -log C = b0 + b1E + b2 log P + b3 (log P)2 using multiple linear regression analysis. Statistical tests showed that the coefficients b2 and b3 were not significantly different from zero and the simpler equation, obtained by omitting the terms in log P, explained 85 per cent of the variance in log C. Earlier reports that the radiosensitization efficiency of nitro compounds in vitro largely depends on the reduction potential were confirmed. The conclusive demonstration that P is unimportant in vitro is valuable in interpreting the results of experiments in vivo, where P is expected to have a much greater influence on biological response.     

Thiol reactive nitroimidazoles: radiosensitization studies in vitro and in vivo

Using Chinese hamster V79 cells in vitro a study has been made of the radiosensitizing properties of 4- or 5-nitroimidazoles substituted in the 2, 5 or 4 position with various halo, sulphur ether, sulphonamide, sulphonate, ether or nitro groups. Values of E17 (the one-electron reduction potential measured versus the normal hydrogen electrode at pH7) vary in the range -178 to -565 mV. All the compounds, with one exception, are more efficient radiosensitizers than would be predicted from their redox potentials, and the factor, C1.6/C1.6, by which a compound is more efficient has been calculated. The second-order rate constants, k2, for reaction of these nitroimidazoles with glutathione and/or dithiothreitol were determined. Within each class of nitroimidazole there is a trend for k2 to increase with increasing redox potential. However, there is no clear trend between k2 and C1.6/C1.6. The concentration required to cause a 50 per cent depletion of intracellular glutathione was determined for selected compounds, as was the ability of glutathione-S-transferase to catalyse reaction with thiols. These observations suggested that the relative thiol reactivity measured under chemically controlled conditions does not necessarily indicate thiol reactivity intracellularly. Studies using the MT tumour in mice showed that the high levels of radiosensitization seen in vitro could not be duplicated in vivo. This was attributed to thiol reactivity, resulting in low metabolic stability and rapid depletion of sensitizer in vivo.     

Antioxidant capacity of flavanols and gallate esters: pulse radiolysis studies

Reactivities of several proanthocyanidins (monomers of condensed tannins) and gallate esters (representing hydrolyzable tannins) with hydroxyl radicals, azide radicals, and superoxide anions were investigated using pulse radiolysis combined with kinetic spectroscopy. We determined the scavenging rate constants and the decay kinetics of the aroxyl radicals both at the wavelength of the semiquinone absorption (275 nm) and the absorption band of the gallate ester ketyl radical (400-420 nm). For most compounds second-order decay kinetics were observed, which reflect disproportionation of the semiquinones. In the case of the oligomeric hydrolysable tannins, pentagalloyl glucose and tannic acid, the decay kinetics were more complex involving sequential first-order and second-order reactions, which could only be resolved by kinetic modeling. A correlation of the reaction rates with hydroxyl radicals (k*OH) with the number of adjacent aromatic hydroxyl groups (i.e., representing catechol and/or pyrogallol structures) was obtained for both condensed and hydrolyzable tannins. Similar correlation for the reactions with azide radicals and superoxide anions are less obvious, but exist as well. We consider proanthocyanidins superior radical scavenging agents as compared with the monomeric flavonols and flavones and propose that these substances rather than the flavonoids proper represent the antioxidative principle in red wine and green tea.     

Generation of nitro radical anions of some 5-nitrofurans, 2- and 5-nitroimidazoles by norepinephrine, dopamine, and serotonin. A possible mechanism for neurotoxicity caused by nitroheterocyclic drugs

Catecholamine neurotransmitters such as norepinephrine, dopamine, and related catecholamine derivatives reduce nitroheterocyclic drugs such as nitrofurantoin, nifurtimox, nifuroxime, nitrofurazone, misonidazole, and metronidazole in slightly alkaline solutions. Drugs which contain 5-nitrofurans are reduced at lower pH than drugs which contain 2- and 5-nitroimidazoles. 5-Nitroimidazole derivatives such as metronidazole and ronidazole are known to be more difficult to reduce than 2-nitroimidazole derivatives, due to their lower redox potential. Catecholamines, when reducing nitro drugs, undergo concomitant oxidation to form semiquinone radicals. Both semiquinone radicals and nitro anion radicals formed in a reaction of nitro drug and catecholamine derivative were detected by electron spin resonance spectroscopy. Oxygen consumption studies in solutions containing nitro drug and catecholamine derivative showed that nitro anion radicals formed under aerobic conditions reduce oxygen to form the superoxide radical and hydrogen peroxide. Quinones formed in the reaction of catecholamine and nitro drug were detected by optical spectroscopy. Biosynthetic precursors and some metabolic products of catecholamines were also used in these studies, and they all exhibited reactions similar to catecholamines. Bovine chromaffin granules which synthesize and store catecholamines produced the nitrofurantoin anion radical when intact granules were treated with nitrofurantoin. These radicals formed inside the granules were observed by ESR spectroscopy. The formation of nitrofurantoin radical, semiquinone radicals of catecholamines, and oxygen-derived radicals by chromaffin granules is proposed to cause damage to adrenal medulla, and this process may lead to neurotoxicity.     

Studies on the induction of sex-linked recessive lethal mutations in Drosophila melanogaster by nitroheterocyclic compounds

24 nitroheterocyclic compounds were investigated for their capacity to induce sex-linked recessive lethals in Drosophila, by the adult feeding technique, and in some cases injection or larval-feeding methods. Out of 9 5-nitroimidazoles, ZK 26.173 and ZK 25.095 (moxnidazole) were clearly active whereas nimorazole and ronidazole were marginally mutagenic. Out of 10 5-nitrofurans, nitrovin, furazolidone and furaltadone were unambiguously mutagenic, whereas nitrofurantoin was a borderline case. Nitrofurans were active at lower molar concentrations than nitroimidazoles. Out of a group of 5 related nitro compounds (2 nitrothiophenes, picrolonic acid, niridazole and 4-NQO), only 4-NQO was clearly mutagenic, when fed to larvae. Experiments with germ-free flies showed that, for ZK 26.173 and furazolidone, the gut flora of Drosophila do not play a role in the activation of the compounds to mutagenic metabolites. Furazolidone, 4-NAO, ZK 26.173, ZK 25.095 and furaltadone were tested in mal and cin strains, both of which lack xanthine dehydrogenase and aldehyde oxidase. The latter enzyme and xanthine oxidase are known to carry out nitro reduction in mammalian tissues. For ZK 26.173, the mutation frequencies were drastically reduced in the enzyme-deficient strains, indicating the involvement of one of these enzymes in the activation of this substance.     

Electron Transfer Reactions in RB90745, A Bioreductive Drug Having Both Aromatic N-Oxide and Nitroarene Moieties

The bifunctional hypoxia-specific cytotoxin RB90745, has a nitroimidazole moiety attached to an imidazo[1,2,-a]quinoxaline mono-N-oxide with a spacer/linking group. The reduction chemistry of the drug was studied by pulse radiolysis using the one electron reductant CO₂^˙-. As N-oxides and nitro compounds react with CO₂^˙- at diffusion controlled rates, initial reaction produced a mixture of the nitro radical (λ_max 410 nm) and the N-oxide radical (λ_max 550 nm) in a few microseconds. Subsequently an intramolecular electron transfer (IET) was observed (k = 1.0 ± 0.25 × 10³ s^-1 at pH 5-9), from the N-oxide to the more electron-affinic nitro group. This was confirmed by the first order decay rate of the radical at 550 nm and formation at 410 nm, which was independent of both the concentration of the parent compound and the radicals. The rates of electron transfer and the decay kinetics of the nitro anion radicals were pH dependent and three different pK_aS could be estimated for the one electron reduced species: 5.6 (nitroimidazole group) and 4.3, and 7.6 (N-oxide function). The radicals react with oxygen with rate constants of 3.1 × 10⁷ and 2.8 × 10⁶ dm³ mol^-1 s^-1 observed at 575 nm and 410 nm respectively. Steady state radiolysis studies indicated four electron stoichiometry for the reduction of the compound.     

Electrochemical Characteristics of Nitroheterocyclic Compounds of Biological Interest. VIII Stability of Nitro Radical Anions from Cyclic Voltammetric Studies

The stability of the one electron addition product of four biologically important nitroheterocyclic compounds has been examined electrochemically. Using cyclic voltammetry the tendency of the nitro radical anion to undergo disproportionation was studied by two methods of analysis. The first was based on determining the voltammetric time-constant required for half of the reduction product, RNO₂, to react further. The second concerned the minimum volume of dimethylformamide which had to be added to the aqueous electrolytic medium to give a specific cyclic voltammetric response. Both methods were found to compare well with the results obtained for RNO₂T stabilities using a theoretically derived procedure for a second order reaction following a charge-transfer step. The use of these alternative approaches for quantifying the reactivity of reduction products is discussed. The time-constant method in particular may be useful in studying complex reaction pathways.     

Correlation of kinetic parameters of nitroreductase enzymes with redox properties of nitroaromatic compounds

The well-established mechanism of regeneration of the parent nitro compound by the reaction of the nitro anion radical with oxygen in aerobic systems is the basis of the correlation of kinetic parameters of purified flavoenzymes with electron affinities of some selected nitroaryl and nitroheterocyclic compounds. We have found that there is a linear relationship between log Vmax/Km and the one-electron reduction potentials of these compounds and that the measured values of redox dependence for these compounds is similar to that determined by other methods. Our results support the proposal of a rate-determining single electron-transfer as the initial step in the reduction of nitro compounds by purified flavoenzymes and are discussed in terms of the Marcus electron transfer theory.     

Nitration activates tyrosine toward reaction with the hydrated electron

3-Nitrotyrosine has been reported as an important biomarker of oxidative stress that may play a role in a variety of diseases. In this work, transient UV-visible absorption spectra and kinetics observed during the reaction of the hydrated electron, e(aq)(-), with 3-nitrotyrosine and derivatives thereof were investigated. The absorption spectra show characteristics of aromatic nitro anion radicals. The absorptivity of radical anion product at 300 nm is estimated to be (1.0 ± 0.2) × 10(4) M(-1) cm(-1) at pH 7.3. The rate constants determined for the reaction of e(aq)(-) with 3-nitrotyrosine, N-acetyl-3-nitrotyrosine ethyl ester and glycylnitrotyrosylglycine at neutral pH (3.0 ± 0.3) × 10(10) M(-1) s(-1), (2.9 ± 0.2) × 10(10) M(-1) s(-1) and (1.9 ± 0.2) × 10(10) M(-1) s(-1), respectively, approach the diffusion-control limit and are almost two orders of magnitude higher than those for the reactions with tyrosine and tyrosine-containing peptides. The magnitude of the rate constants supports reaction of e(aq)(-) at the nitro group, and the product absorbance at 300 nm is consistent with formation of the nitro anion radical. The pH dependence of the second-order rate constant for e(aq)(-) decay (720 nm) in the presence of 3-nitrotyrosine shows a decrease with increasing pH, consistent with unfavorable electrostatic interactions. The pH dependence of the second-order rate constant for formation of radical anion (300 nm) product suggests that deprotonation of the amino group slows the rate, which indicates that deamination to form the 1-carboxy-2-(4-hydroxy-3-nitrophenyl)ethyl radical occurs. We conclude that the presence of the nitro group activates tyrosine and derivatives toward reaction with e(aq)(-) and can affect the redox chemistry of biomolecules exposed to oxidative stress.     

Kinetic behavior of the monodehydroascorbate radical studied by pulse radiolysis

The reactions of the monodehydroascorbate radical (As.-) with various biological molecules were investigated by pulse radiolysis. As.- reacted with both fully reduced and semiquinone forms of hepatic NADH-cytochrome b5 reductase with second-order rate constants of 4.3 x 10(6) and 3.7 x 10(5) M-1 s-1, respectively, at pH 7.0. In contrast, no reaction of As.- with ferrous cytochrome b5 could be detected by pulse radiolysis, whereas the oxidation of cytochrome b5 by As.- was observed by ascorbate-ascorbate oxidase method. This suggests that the rate constant of As.- with the ferrous cytochrome b5 must be several orders in magnitude smaller than that of the disproportionation of As.-. On the other hand, As.- reduced Fe3+EDTA with a second-order rate constant of 4.0 x 10(6) M-1 s-1 but did not reduce ferric hemoproteins such as metmyoglobin, methemoglobin, and cytochrome b5 by either the pulse radiolysis or the ascorbate-ascorbate oxidase method.     

Nucleotide radical oxidation and addition reactions with cellular radiosensitizers

The yields of inorganic phosphate (iPO₄) released from deoxygenated solutions of irradiated purine 5′-mononucleotides are enhanced in the presence of low concentrations of oxygen, or such electron-affinic cellular radiosensitizers as p-nitroacetophenone and nitrofurans. The degree of radiosensitization increases with the sensitizer's electron-affinity, oxygen showing an approximately two-fold sensitization. Other electron-affinic cellular radiosensitizers, including the stable free radical triacetonamine-N-oxyl (TAN), protect against iPO₄ release, the degree of protection increasing with the sensitizer's electron-affinity. These findings are consistent with competition between nucleotide free radical oxidation and addition to sensitizer. Their relevance to mechanisms of radiosensitization is discussed.     

Structure-activity relationships in the development of hypoxic cell radiosensitizers. II. Cytotoxicity and therapeutic ratio.

This paper describes measurements of the aerobic cytotoxicity of 42 nitroaromatic and nitroheterocyclic compounds towards Chinese Hamster cells in vitro. The results of acute and chronic exposure were quantified, and the concentration C required to achieve a standard response estimated. Fitting the data to an equation of the form - log C = b0 + b1E, where E is the one-electron reduction potential, explained 47 and 71 per cent of the variance in the acute and chronic aerobic cytotoxicity respectively. The addition of further terms to the equation, quantifying partition properties, was not statistically significant. The coefficient b1 was similar for both acute and chronic exposure; the dependence of both cytotoxicity and radiosensitization efficiency on reduction potential was also similar. A therapeutic ratio derived from these in vitro measurements showed no dependence on redox or partition properties. The insensitivity of cytotoxicity and radiosensitization properties to variations in molecular structure, other than those which influence redox behaviour, offers exceptional flexibility in developing compounds of improved therapeutic ratio.     

The one-electron reduction of uroporphyrin I by rat hepatic microsomes

Uroporphyrin I, which accumulates in body tissues of congenital erythropoietic porphyria patients, can undergo an enzymatic one-electron reduction to the porphyrin anion radical when a suitable reducing cofactor is present. We have demonstrated, in the absence of light, that anaerobic microsomal incubations containing NADPH and uroporphyrin I give an electron spin resonance spectrum consistent with the enzymatic formation of a porphyrin anion free radical. This radical undergoes a second-order decay (k2 approximately 10(5) M-1 s-1) due to nonenzymatic disproportionation of the radical. Aerobic microsomal incubations were also investigated for the reduction of oxygen to superoxide by monitoring oxygen consumption and the spin-trapping of superoxide. These experiments demonstrate that electron transfer from the porphyrin radical to molecular oxygen does occur, but due to the slow formation of the radical anion, no oxygen consumption above the basal level could be detected in the microsomal incubations. The photoreduction of uroporphyrin I in aerobic and anaerobic incubations was also investigated.     

Direct electron spin resonance detection of free radical intermediates during the peroxidase catalyzed oxidation of phenacetin metabolites

The oxidation of the phenacetin metabolites p-phenetidine and acetaminophen by peroxidases was investigated. Free radical intermediates from both metabolites were detected using fast-flow ESR spectroscopy. Oxidation of acetaminophen with either lactoperoxidase and hydrogen peroxide or horseradish peroxidase and hydrogen peroxide resulted in the formation of the N-acetyl-4-aminophenoxyl free radical. Totally resolved spectra were obtained and completely analyzed. The radical concentration was dependent on the square root of the enzyme concentration, indicating second-order decay of the radical, as is consistent with its dimerization or disproportionation. The horseradish peroxidase/hydrogen peroxide-catalyzed oxidation of p-phenetidine (4-ethoxyaniline) at pH 7.5-8.5 resulted in the one-electron oxidation products, the 4-ethoxyaniline cation free radical. The ESR spectra were well resolved and could be unambiguously assigned. Again, the enzyme dependence of the radical concentration indicated a second-order decay. The ESR spectrum of the conjugate base of the 4-ethoxyaniline cation radical, the neutral 4-ethoxyphenazyl free radical, was obtained at pH 11-12 by the oxidation of p-phenetidine with potassium permanganate.     

Targeting radiosensitizers to DNA by attachment of an intercalating group: nitroimidazole-linked phenanthridines

The nitroimidazole-linked phenanthridine series of compounds (NLP-1, 2, and 3) were synthesized under the assumption that it should be possible to enhance the molar efficiency of 2-nitroimidazoles as hypoxic cell radiosensitizers and cytotoxins by targeting them to their likely site of action, DNA. The targeting group chosen was the phenanthridine moiety, the major component of the classical DNA intercalating compound, ethidium bromide. The sole difference between the compounds is the length of the hydrocarbon chain linking the nitroimidazole to the phenanthridine. The phenanthridine group with a three-carbon side chain, P-1, was also synthesized to allow studies on the effect of the targeting group by itself. The ability of the compounds to bind to DNA is inversely proportional to their linker chain length with binding constant values ranging from approximately 1 x 10(5) mol-1 for NLP-2 to 6 x 10(5) mol-1 for NLP-3. The NLP compounds show selective toxicity to hypoxic cells at 37 degrees C at external drug concentrations 10-40 times lower than would be required for untargeted 2-nitroimidazoles such as misonidazole in vitro. Toxicity to both hypoxic and aerobic cells is dependent on the linker chain: the shorter the chain, the greater the toxicity. In addition, the NLP compounds radiosensitize hypoxic cells at external drug concentrations as low as 0.05 mM with almost the full oxygen effect being observed at a concentration of 0.5 mM. These concentrations are 10-100 times lower than would be required for similar radiosensitization using misonidazole. Radiosensitizing ability is independent of linker chain length. The present compounds represent prototypes for further studies of the efficacy and mechanism of action of 2-nitroimidazoles targeted to DNA by linkage to an intercalating group.     

Free radical metabolism of antiparasitic agents

In recent years it has been apparent that many of the known antiparasitic drugs produce free radicals. Intracellular reduction followed by autooxidation yielding O.-2 and H2O2 has been suggested as the mode of action of nifurtimox on Trypanosoma cruzi and as the basis of its toxicity in mammals. On the other hand, free radical intermediates that do not generate oxygen-reduction products under physiological conditions have been found in the metabolic pathways of other antiparasitic nitro compounds (benznidazole, metronidazole, and other 5-nitroimidazoles) used in the treatment of diseases such as Chagas' disease, trichomoniasis, giardiasis, balantidiasis, amebiasis, and schistosomiasis. In these cases, as well as in the case of niridazole (used in the treatment of schistosomiasis), covalent binding or other interactions of the intermediates of nitroreduction with parasite macromolecules are possibly involved in their toxicity. Redox cycling of these compounds under aerobic conditions appears to be a detoxification reaction by inhibiting net reduction of the drugs.