Reactions in the Radiosensitizer Misonidazole Induced by Low-Energy (0-10 eV) Electrons.

Misonidazole (MISO) was considered as radiosensitizer for the treatment of hypoxic tumors. A prerequisite for entering a hypoxic cell is reduction of the drug, which may occur in the early physical-chemical stage of radiation damage. Here we study electron attachment to MISO and find that it very effectively captures low energy electrons to form the non-decomposed molecular anion. This associative attachment (AA) process is exclusively operative within a very narrow resonance right at threshold (zero electron energy). In addition, a variety of negatively charged fragments are observed in the electron energy range 0-10 eV arising from dissociative electron attachment (DEA) processes. The observed DEA reactions include single bond cleavages (formation of NO2-), multiple bond cleavages (excision of CN-) as well as complex reactions associated with rearrangement in the transitory anion and formation of new molecules (loss of a neutral H2O unit). While any of these AA and DEA processes represent a reduction of the MISO molecule, the radicals formed in the course of the DEA reactions may play an important role in the action of MISO as radiosensitizer inside the hypoxic cell. The present results may thus reveal details of the molecular description of the action of MISO in hypoxic cells.

Mitochondrial respiratory chain features after gamma-irradiation.

Radiation provokes damage to DNA but also to membrane and protein structure. Radiolysis is a tool used very often in the study of free radical biological effects and of scavenger molecules effectiveness. Nitroimidazoles have been demonstrated to enhance the radiation effects on biological structures. The studies we have performed on isolated mitochondria irradiated, with and without nitroimidazoles, at a radiation dose equal to LD90, indicate that this treatment is not able to affect the structural and functional features investigated (ubiquinone-10, fatty acids, respiratory cytochrome levels or membrane fluidity and respiratory enzymatic activities), suggesting that an involvement of such externally produced radicals on membrane damage is unlikely. Moreover it was ascertained that the mitochondrial redox activities do not take part into the intracellular nitroimidazole reduction.

Radiation-induced energy migration within solid DNA: the role of misonidazole as an electron trap.

The "in-pulse" luminescence emission from solid DNA produced upon irradiation with electron pulses of energy below 260 keV has been investigated in vacuo at 293 K to gain an insight into the existence of radiation-induced charge/energy migration within DNA. The DNA samples contained misonidazole in the range 3 to 330 base pairs per misonidazole molecule. Under these conditions greater than 90% of the total energy is deposited in the DNA. The in-pulse radiation-induced luminescence spectrum of DNA was found to be critically dependent upon the misonidazole content of DNA. The luminescence intensity from the mixtures decreases with increasing content of misonidazole, and at the highest concentration, the intensity at 550 nm is reduced to 50% of that from DNA only. In the presence of 1 atm of oxygen, the observed emission intensity from DNA in the wavelength region 350-575 was reduced by 35-40% compared to that from DNA in vacuo. It is concluded that electron migration can occur in solid mixtures of DNA over a distance of up to about 100 base pairs.

Effect of radiation-induced reduction of nitroimidazoles on biologically active DNA.

Radiation-chemical reductions have been carried out with several nitroimidazoles. Reduction of these drugs in the presence of single-stranded phi chi 174 DNA causes extensive lethal damage. However, relatively stable (end) products, do not contribute to the damage, although glyoxal is potentially toxic. This demonstrates that a short-lived intermediate in the reduction process is responsible. Further, the quantity of damage in the DNA depends on both dose (reduction)-rate and also the nature of the drug.

Stable reduction product of misonidazole.

The predominant stable product (greater than 80%) of the anaerobic radiation chemical reduction (pH 7, formate, N2O) of misonidazole (MISO) has been identified as the cyclic guanidinium ion MISO-DDI, a 4,5-dihydro-4,5-dihydroxyimidazolium ion. This cation was prepared as its sulfate salt by the reaction of glyoxal and the appropriate N-substituted guanidinium sulfate. Its formation during MISO reduction was established by NMR spectral comparison and by derivatization as glyoxal bis-oxime, which was formed in 86% yield in fully reduced systems. The toxicity of pure MISO-DDI X sulfate was examined in vivo (C3H mice) and in vitro (CHO cells). This product is less toxic than the parent MISO and free glyoxal. A reactive, short-lived, intermediate is suggested as the agent responsible for the toxicity of MISO under hypoxic conditions.

Induction of DNA strand breaks by RSU-1069, a nitroimidazole-aziridine radiosensitizer. Role of binding of both unreduced and radiation-reduced forms to DNA, in vitro.

[2-14C]-RSU-1069 [1-(2-nitro-1-imidazolyl)-3-(1-aziridino)-2-propanol], either as a parent (unreduced) or following radiation reduction, binds to calf thymus DNA in vitro. Radiation-reduced RSU-1069 binds to a greater extent and more rapidly than the parent compound. RSU-1137, a nonaziridino analogue of RSU-1069, binds following radiation reduction. Radiation-reduced misonidazole (1-(2-nitro-1-imidazolyl)-3-methoxy-2-propanol) exhibits binding ratios a thousand-fold less than those of reduced RSU-1069. There is no evidence for binding of parent misonidazole. Both parent and reduced RSU-1069 cause single strand breaks (ssbs) in pSV2 gpt plasmid DNA with the reduced compound causing a greater number of breaks. Parent and reduced RSU-1137 and misonidazole do not cause ssbs. It is inferred that the aziridine moiety present in both parent and reduced RSU-1069 is required for ssb production. RSU-1069 reacts with inorganic phosphate probably via nucleophilic ring-opening of the aziridine fragment. Incubation of plasmid DNA with reduced RSU-1069 in the presence of either phosphate or deoxyribose-5-phosphate at concentrations greater than 0.35 mol dm-3 prevents strand breakage, whereas 1.2 mol dm-3 deoxyribose does not protect against strand breakage formation. From these findings it is proposed that the observed binding to DNA occurs via the aziridine and the reduced nitro group of RSU-1069 and that these two have different target sites. Binding to DNA via the reduced nitro group may serve to increase aziridine attack due to localization at or near its target.

The oxygen dependence of the reduction of nitroimidazoles in a radiolytic model system.

Radiation chemical reductions using eaq- and CO2- have been carried out in the presence of oxygen with metronidazole, p-nitroacetophenone, misonidazole and three other 2-nitroimidazoles. Low concentrations of oxygen were found to effectively inhibit the reduction of the first two compounds while much higher concentrations of oxygen were required for all of the 2-nitroimidazoles. These results parallel in vitro and in vivo experiments with metronidazole and misonidazole which also indicate that the reduction of the latter is significantly less inhibited by oxygen. Kinetic modelling of the radiochemical system suggests that the explanation for the differences lies in different reactions of the nitro radical anions; it appears that the anion derived from metronidazole undergoes disproportionation while that derived from misonidazole undergoes a unimolecular decay.

Reductive fragmentation of 2-nitroimidazoles: amines and aldehydes.

Glyoxal has been identified as a product in the fragmentation of reduced 2-nitroimidazole radiosensitizers. Quantitative analysis of glyoxal as its bis (2,4-dinitrophenylhydrazone) derivative shows that it is formed in good yield (9-23%) in a variety of 2-nitroimidazoles. In addition to glyoxal a second as-yet-unidentified carbonyl compound, and a series of amines are formed when reduced 2-nitromidazoles fragment in the presence of water. One of the amines derived from misonidazole is identified as 1-amino-3-methoxypropan-2-ol, the product of extensive ring cleavage. Radiation chemical reduction of the 2-nitromidazoles proceeds with the consumption of 3 electrons for each molecule reduced. This could imply that a radical disproportionation or dimerization step is involved in the reductive degradation of 2-nitroimidazoles.

Radiation-induced reduction of nitroimidazole derivatives in aqueous solution.

The radiation-induced reduction of N1-alkyl substituted 2- and 5-nitroimidazoles in aqueous solution containing sodium formate or 2-propanol was studied at pH 7.0 +/- 0.1 under deaerated conditions. Irrespective of 2- or 5-nitroimidazole, N1-unsubstituted nitroimidazoles (2-nitro-(1a), 4(5)-nitro-(2a), 2-methyl-4(5)-nitro (3a), and 4(5)-methyl-5(4)-nitro- (4a) imidazoles) were reduced stepwise to consume 6 electrons per molecule, whereas N1-alkyl substituted nitroimidazoles (1-methyl-2-nitro (5a) and 1-methyl-5-nitro (6a) imidazoles, misonidazole (7a), and metronidazole (8a] reacted with consumption of 4 electrons. In accord with the stoichiometry for the reduction of N1-unsubstituted nitroimidazoles, the formation of the amino derivatives of (1a)-(4a) was shown by HPLC or colour identification tests. 4-Electron-reduction products of N1-alkyl substituted 2-nitroimidazoles (5a) and (7a) were characterized by 13C and 1H n.m.r. and FDMS measurements, indicating that the hydroxyamino derivative of (5a) as a 4-electron-reduction product isomerizes to an oxime form. The formation of an analogous oxime-type product was also suggested for (7a) together with a product bearing the partially cleaved imidizole ring. The HPLC analysis showed that 4-electron-reduction products of N1-alkyl substituted 5-nitroimidazoles (6a) and (8a) are unstable relative to those of the corresponding 2-nitroimidazoles (5a) and (7a).

Action spectra for ultraviolet photosensitized killing of mammalian cells by misonidazole and para-nitroacetophenone.

V-79 Chinese hamster fibroblasts in monolayer culture were exposed to ultraviolet radiation at 313, 334, 365, 380, and 405 nm in the presence of either misonidazole or para-nitroacetophenone, drugs which act as both photosensitizers and radiosensitizers of cell killing. Survival was measured by a colony-forming assay. The resulting action spectra for cell death photosensitized by the drugs (the reciprocals of the exposures required at each wavelength to reduce cell survival to a given level) closely match their absorption spectra over a range of three orders of magnitude. These results demonstrate that cells can be killed upon excitation of misonidazole or para-nitroacetophenone in the absence of any other types of energy deposition or biomolecular damage.