M.V.M. Lafleur

The Ambivalent Role of Glutathione in the Protection of Dna Against Singlet Oxygen

Glutathione (GSH) was examined with respect to its ability to protect DNA against 1O2 damage. We have found that GSH protected, at least partly, the DNA against inactivation by 1O2. Up to 10 mM the protection increased as a function of GSH concentration. Above 10 mM the protection remained constant and less than expected on the basis of scavenging/quenching of 1O2, in contrast to the protection offered by sodium-azide. Especially at the higher concentrations of GSH the protection against the biological inactivation is accompanied by an increase in single-strand breaks and also probably lethal base damage. However, all together the data suggest that at least in the physiologically important range (0.1-10 mM) GSH is able to protect efficiently against 1O2-induced inactivating DNA damage.

DNA damage induced by reduced nitroimidazole drugs

Five nitroimidazole drugs were reduced electrolytically and by gamma-radiolysis at fast (300 mumoles or 100% per hr) and slow (3-9 mumoles or 1-3% per hr) reduction rates in the presence of Escherichia coli DNA and single stranded or double stranded DNA from the bacteriophage phi X174. The degree of DNA damage depends upon the rate of drug reduction, where slow reduction produces more damage than fast reduction. The efficiency of damage produced is in the order metronidazole greater than ornidazole greater than azomycin greater than misonidazole greater than benznidazole which reveals a linear correlation between the one-electron reduction potential (E17) and the negative logarithm of the concentration of reduced drug at which 37% of the original DNA activity remains. Damage is not influenced by the presence of O2 at least between about 1-100 ppm. We suggest the protonated one-electron nitro radical anion as a possible candidate for the active damaging species and explain the basis of the relative cytotoxicity of these drugs under conditions of hypoxia.

Effects of sulphydryl compounds on the radiation damage in biologically active DNA.

The effect of sulphydryl compounds on the induction of alkali-labile sites and on the contribution of such sites to the inactivation of single-stranded phi X174 DNA was studied. Cysteamine is capable of reacting with DNA radicals, thereby modifying the radiation damage in such a way that the induction of immediate and latent breaks is reduced. This depends on the pH of the solution. With cysteine only, a pH dependent protection, against lethal alkali-labile potential breaks could be observed. The damage other than breaks is not influenced by the presence of sulphydryl compounds.

Alkali-labile sites and post-irradiation effects in gamma-irradiated biologically active double-stranded DNA in aqueous solution.

Gamma-irradiation of double-stranded RF-DNA of bacteriophage phi X174 in aqueous solution in the presence of oxygen produces at least one type of alkali-labile site. It is lethal and gives rise to breaks by alkali and is identical with the damage which becomes manifest by post-irradiation heat treatment. The effect of alkali is dependent on temperature. Furthermore, the excision repair system is not involved in eliminating lethal nucleotide damage in RFI-DNA.

Alkali-labile Sites in Biologically Active DNA: Comparison of Radiation Induced Potential Breaks and Apurinic Sites

Gamma-ray induced alkali-labile sites, which are converted into breaks by alkali or heat, are compared with apurinic sites in both single-stranded and phi X174RF-DNA. It is shown that the kinetics of the conversion into breaks are completely different for both sites. The conclusion is: the gamma-ray induced alkali-labile sites are not identical with apurinic or/and apyrimidinic sites.

Influence of Anoxic Sensitizers on the Radiation Damage in Biologically Active DNA in Aqueous Solution

The competition between biologically active single-stranded phiX174 DNA and the anoxic radiosensitizers metronidazole, misonidazole, paranitroacetophenone or nifuroxime for OH radicals is studied. The results are compared with experiments in which the protection of the DNA by t-butanol is determined. Also the effects of the sensitizers on the chemical nature of the damage (immediate and potential break, immediate and potential base damage) is studied. It is found that in diluted aqueous solutions of DNA these radiosensitizers do not sensitize with respect to the biological inactivation. The only effect observed is a shift from potential to immediate breaks with misonidazole and also nifuroxime.

Repair of Damage in Double-stranded ϕX174 (RF) DNA Due to Radiation-induced Water Radicals

Experiments in which the yields of radiation-induced OH and H radicals were varied, showed that both types of water radicals inactivate phi X174 RF DNA to about the same extent as measured by transfection of the (irradiated) DNA to E. coli wild-type spheroplasts. On the other hand, using spheroplasts prepared from E. coli strains, deficient in one of the proteins involved in excision DNA repair (uvrA- or uvrC-) or in post-replication repair (recA-), clear differences between damage originating from OH or H radical attack were found. Part of the radiation damage due to H radicals appeared to be repairable by an uvrA-gene-dependent repair mechanism, whereas this repair pathway does not play an important role in the case of OH radical damage. The reverse applies to uvrC-gene-dependent repair, which only affects OH radical damage (obtained under anoxic conditions), but has no influence on damage due to H radicals. Irradiation of double-stranded phi X174 (RF) DNA in the presence of oxygen however, yields damage--due to OH radicals only--which appeared not to be sensitive to either uvrC- or uvrA-gene-dependent repair. Furthermore, post-replication repair (recA) has only very little effect on the amount of inactivation by H or OH radicals, when irradiation is carried out under anoxic conditions. We did not find significant inactivation due to hydrated electrons, whether the biological activity was determined by use of wild-type spheroplasts or of strains deficient in excision or post-replication repair proteins.

Alkali-labile Sites and Post-irradiation Effects in Single-stranded DNA Induced by H Radicals

Single-stranded phiX174 DNA in aqueous solutions has been irradiated in the absence of oxygen, under conditions in which only H radicals react with the DNA. It was shown that H radical reactions result in breaks, which contribute approximately 10 per cent inactivation. Further, two types of alkali-labile sites are formed. One is lethal and gives rise to single-strand breaks by alkali and is most probably identical with post-irradiation heat damage and contributes about 33 per cent to the inactivation mentioned above. The other consists of non-lethal damage, partly dihydropyrimidine derivatives, and is converted to lethal damage by alkali. This follows from experiments in which the DNA was treated with osmium-tetroxide, which oxidizes thymine to 5,6-dihydroxy-dihydrothymine. Treatment with alkali of this DNA gives the same temperature dependence as found for the non-lethal alkali-labile sites in irradiated DNA. A similar temperature dependence is found for dihydrothymine and irradiated pyrimidines with alkali.

Biological Relevance of Gamma-ray-induced Alkali-labile Sites in Single-stranded DNA in Aqueous Solutions

Gamma-irradiation in single-stranded phiX174 DNA in aqueous solution in the presence of oxygen produces at least two types of alkali-labile site. One is lethal and gives rise to single-strand breaks by treatment with alkali. The other is non-lethal, but is converted to lethal damage by alkali. The effect of alkali is dependent on temperature. This dependence is different for both types of alkali-labile site.

Electrolytic Reduction of Nitroheterocyclic Drugs Leads to Biologically Important Damage in DNA

The effect of electrolytic reduction of nitroimidazole drugs on biologically active DNA was studied. The results show that reduction of the drugs in the presence of DNA affects inactivation for both double-stranded (RF) and single-stranded phi X174 DNA. However, stable reduction products did not make a significant contribution to the lethal damage in DNA. This suggests that probably a short-lived intermediate of reduction of nitro-compounds is responsible for damage to DNA.