M.Vincent M. Lafleur

Radiosensitization of human glioma cells by cyclooxygenase-2 (COX-2) inhibition: Independent on COX-2 expression and dependent on the COX-2 inhibitor and sequence of administration

Purpose: Patients with a malignant glioma have a very poor prognosis. Cyclooxygenase-2 (COX-2) protein is regularly upregulated in gliomas and might be a potential therapeutic target. The effects of three selective COX-2 inhibitors were studied on three human glioma cell lines. Materials and methods: The selective COX-2 inhibitors NS-398, Celecoxib and Meloxicam and three human glioma cell lines (D384, U251 and U87) were used. Cell growth was assessed by a proliferation assay, the interaction with radiation (0 – 6 Gy) was studied using the clonogenic assay and cell cycle distribution was determined by FACS (fluorescence-activated cell sorting) analysis. Results: All COX-2 inhibitors reduced proliferation of the glioma cell lines irrespective of their COX-2 expression level. Incubation with 200 μM NS-398 24 h before radiation enhanced radiation-induced cell death of D384 cells and 750 μM Meloxicam resulted in radiosensitization of D384 and U87 cells. No radiosensitization was observed with COX-2 inhibitor administration after radiotherapy. Treatment of D384 with NS-398 (200 μM) or Celecoxib (50 μM) and U87 with NS-398 (200 μM) after radiation resulted even in radioprotection. Conclusions: Effectiveness of COX-2 inhibitors on cell proliferation and radio-enhancement was independent of COX-2 protein expression. The sequence of COX-2 inhibitor addition and irradiation is very important.

Effects of the ortho-quinone and catechol of the antitumor drug VP-16-213 on the biological activity of single-stranded and double-stranded ΦX174 DNA

We have studied the effects of the recently reported two new metabolites of the antitumor agent VP-16-213, the ortho-dihydroxy derivative or catechol and the ortho-quinone, on the biological activity of single-stranded and double-stranded phi X174 DNA, the binding of the metabolites to calf thymus DNA and the conversion of the catechol into the ortho-quinone. Evidence was obtained for the oxidation of the catechol into the ortho-quinone and for the fact that the ortho-quinone is the metabolite of VP-16-213 responsible for its binding to rat liver microsomal proteins. The catechol and ortho-quinone of VP-16-213 were found to bind 7-9 times more strongly to calf thymus DNA than VP-16-213 itself. In contrast to the parent compound VP-16-213, the catechol as well as the ortho-quinone inactivated both single-stranded (ss) and double-stranded (RF) biologically active phi X174 DNA. The mean T37-values for inactivation of ss and RF phi X174 DNA by 2.2 x 10(-4)M catechol at 37 degrees and pH 7.4 were 96 and 640 min, respectively. Reduction of the ortho-quinone by NADPH cytochrome P-450 reductase resulted in formation of the catechol. The system ortho-quinone/NADPH cytochrome P-450 reductase inactivated ss phi X174 DNA with a mean T37-value of 454 min, and this inactivation was inhibited by DMSO. The mean T37-value for inactivation of ss phi X174 DNA by 1.8 x 10(-4) M ortho-quinone at 37 degrees and pH 4.0 was 24 min. The chemical stability of the ortho-quinone and the extent of inactivation of ss phi X174 DNA by the ortho-quinone were both pH-dependent: at higher pH the ortho-quinone was less stable and gave less inactivation of DNA. The aqueous decomposition product(s) of the ortho-quinone formed at pH 7.4 inactivated ss phi X174 DNA with a mean T37-value of 175 min. The rate of inactivation of RF phi X174 DNA by the ortho-quinone at pH 4.0 was twice as low as the rate of inactivation of ss phi X174 DNA: T37 = 49 min. When using excision repair deficient E. coli mutants (uvrA- or uvrC-), a higher inactivation of RF phi X174 DNA was found: T37 = 29 min for uvrA- E. coli, indicating that a part of the DNA damage introduced by the incubation with ortho-quinone is removed by excision repair.(ABSTRACT TRUNCATED AT 400 WORDS)

L-Dopa stimulates expression of the antioxidant enzyme NAD(P)H:quinone oxidoreductase (NQO) in cultured astroglial cells.

The autooxidation of L-Dopa, a catecholamine used in the symptomatic treatment of Parkinsons disease, generally yields reactive oxygen species and neurotoxic quinones. NAD(P)H:quinone oxidoreductase (NQO) is a flavoenzyme that is implicated in the detoxication of quinones, including those formed during L-Dopa autooxidation. Through the action of this enzyme, deleterious redox-labile quinones are turned into less toxic and more stable hydroquinones that are amenable to further detoxication and/or cellular excretion. In the present study, using primary rat astrocytes and C6 astroglioma as a model to evaluate the neuroprotective response of astroglial cells upon exposure to L-Dopa, we demonstrate that this compound, or more correctly its quinone (auto)oxidation products, up-regulates astroglial NQO in a time- and concentration-dependent way as assessed at the level of mRNA expression, protein level, and enzymatic activity. Moreover, under similar conditions cellular glutathione content was enhanced. It is concluded that, similar to glutathione, the oxidative stress limiting NQO is likely to contribute to the capacity of astroglial cells to protect dopaminergic neurons against L-Dopa, and, hence, may be considered as a potential target for the development of neuroprotective strategies for Parkinsons disease.

C/G to A/T transversions represent the main type of mutation induced by γ-irradiation in double-stranded M13mp10 DNA in a nitrogen-saturated solution

To get more insight into the possible mutagenic consequences of DNA damage induced by radiation-generated H radicals (.H), a nitrogen-saturated solution of double-stranded (ds) M13mp10 DNA in phosphate buffer was irradiated with gamma-rays. Under these conditions 55% of the DNA-damaging species consists of H radicals and 45% of OH radicals (.OH). The mutations were investigated in a 144-bp mutational target sequence inserted into the lacZ alpha gene. A very specific mutation spectrum was obtained with respect to the type of mutations. Twenty out of the 28 radiation-induced mutations were C/G to A/T transversions; the remaining 8 mutations were 4 C/G to G/C transversions, 2 C/G to T/A transitions, one T/A to A/T transversion and only one -1 bp deletion. The mutations were rather randomly distributed along the 144-bp mutation target sequence with no clear mutational hot spots. When these results are compared with those we have obtained previously after irradiation of ds M13mp10 DNA under O2 (100% .OH) or N2O (90% .OH; 10% .H) (Hoebee et al., 1988, 1989), the data strongly suggest that H radicals may be responsible for the observed C/G to A/T transversions but not for -1 bp deletions.

Influence of nucleotide excision repair of Escherichia coli on radiation-induced mutagenesis of double-stranded M13 DNA

To investigate a possible role of nucleotide excision repair (NER) of E. coli in the removal of gamma-radiation-induced DNA lesions, double-stranded M13mp10 DNA, which contains a part of the lac operon, including the promoter/operator region, the lacZ alpha gene and a 144 basepair (bp) inframe insert in the lacZ alpha gene, as mutational target was gamma-irradiated in a phosphate buffer under N2. Subsequently, the radiation-exposed DNA was transfected to wild-type or NER-deficient (uvrA-) E. coli, mutants in the mutational target selected, followed by characterization of the mutants by sequence analysis. Both the mutations obtained from wild-type and uvrA- E. coli appeared to consist mainly of bp substitutions. However, in contrast to wild-type cells, a relatively large proportion of the mutations obtained from the NER-deficient cells (about 25%) is represented by -1 bp deletions, indicating that NER may be responsible for the removal of lesions which cause this particular type of frameshift. Comparison of the bp substitutions between both E. coli strains showed considerable differences. Thirty per cent of all bp substitutions in the NER-deficient host are T/A-->C/G transitions which are virtually absent in wild-type E. coli. This indicates that NER is involved in the elimination of lesions responsible for these transitions. This may also be true for a part of the lesions which cause C/G-->T/A transitions, which make up 52% of the bp substitutions in uvrA- cells versus 17% in wild-type cells. Strikingly, C/G-->G/C transversions appeared to be only formed in wild-type, where they make up 22% of all bp substitutions, and not in the NER-deficient E. coli. This result suggests, that due to the action of NER, a particular type of mutation may be introduced. A similar indication holds for C/G-->A/T transversions, which are predominant in wild-type (58%) and in the minority in uvrA- cells (15%).

The influence of combined Fpg- and MutY-deficiency on the spontaneous and γ-radiation-induced mutation spectrum in the lacZα gene of M13mp10

Abstract One of the most predominating oxidative DNA damages, both spontaneously formed and after γ-radiation is 7,8-dihydro-8-oxoguanine (8oxoG). This 8oxoG is a mutagenic lesion because it can mispair with adenine instead of the correct cytosine leading to G:C to T:A transversions. In Escherichia coli (E. Coli) base excision repair (BER) is one of the most important repair systems for the repair of 8oxoG and other oxidative DNA damage. An important part of BER in E. coli is the so-called GO system which consists of three repair enzymes, MutM (Fpg), MutY and MutT which are all involved in repair of 8oxoG or 8oxoG mispairs. The aim of this study is to determine the effect of combined Fpg- and MutY-deficiency on the spontaneous and γ-radiation-induced mutation spectrum of the lacZα gene. For that purpose, non-irradiated or γ-irradiated double-stranded (ds) M13mp10 DNA, with the lacZα gene inserted as mutational target sequence was transfected into an E. coli strain which is deficient in both Fpg and MutY (BH1040). The resulting mutation spectra were compared with the mutation spectra of a fpg− E. coli strain (BH410) and a wild type E. coli strain (JM105) which were determined in an earlier study. The results of the present study indicate that combined Fpg- and MutY-deficiency induces a large increase in G:C to T:A transversions in both the spontaneous and γ-radiation-induced mutation spectra of BH1040 (fpg−mutY−) as compared to the fpg− and the wild type strain. Besides the increased levels of G:C to T:A transversions, there is also an increase in G:C to C:G transversions and frameshift mutations in both the spontaneous and γ-radiation-induced mutation spectra of BH1040 (fpg−mutY−).

Influence of the UV-activated SOS response on the γ-radiation-induced mutation spectrum in the lacI gene

Previous studies of our group have shown that intracellular or extracellular gamma-irradiation of the lacI gene results in different mutational spectra. One cause for these differences might be the error-prone SOS response, which is activated in the intracellular situation by gamma-irradiation but not in the extracellular situation. Since UV-radiation is a well-established strong inducer of the SOS response, we used bacterial host cells, pretreated with UV-light to study the influence of the SOS response on the gamma-radiation-induced mutation spectrum in the lacI gene in the extracellular situation. If the SOS response was activated, mutations on A:T base pairs and frameshift mutations accounted for 16% and 12% of all mutations, respectively, but they were hardly detected in the absence of an induced SOS response. G:C to T:A transversions increased from 14% to 24% in the presence of an activated SOS response. We can therefore conclude from this study, that SOS-induction of host cells by UV-light influences the extracellular mutation spectrum in the lacI gene, with respect to mutations on A:T base pairs, G:C to T:A transversions and frameshift mutations. This conclusion is supported by the fact that the previously obtained intracellular gamma-radiation-induced mutation spectrum in the lacI gene, in which the SOS response is also involved, shows great similarities with the extracellular mutation spectrum in the presence of an activated SOS response in this study.

Effect of the sulfhydryl compound cysteamine on gamma-radiation-induced mutations in double-stranded M13 DNA

Sulfhydryl compounds can protect DNA against free-radical-induced DNA damages not only by scavenging of radicals, but also by chemical non-enzymatic repair or modification of such damages by hydrogen-donation. To investigate the influence of chemical repair and modification on mutations, induced by gamma-radiation-generated free radicals (.OH, .H), phosphate-buffered aqueous solutions of double-stranded (ds) M13 DNA were exposed to gamma-rays under N2 in the presence of 5 mM cysteamine. The exposed DNA was subsequently transfected to wild-type E. coli and mutations in the mutational target were characterized. This target in fact contains three different target sequences, i.e., the lac promoter/operator, the lacZ alpha gene and a 144 bp inframe insert. The mutation spectrum obtained was compared with those in the absence of cysteamine under N2 and N2O. In the latter case, the ratio of .OH and .H available for reacting with DNA is about the same as under N2 + cysteamine. The results show that chemical repair and/or modification by cysteamine of potentially lethal lesions takes place, leading to a much higher survival of ds M13 DNA in the presence of cysteamine than could be expected on basis of scavenging of .OH and .H alone. This higher survival appeared to be accompanied with a higher mutation induction. However, the N2 + cysteamine mutation spectrum shows a remarkable resemblance with the N2O-spectrum. This holds for the total mutation target, as well as each of the three targets, although the mutations obtained in each of the three targets under the same irradiation conditions are quite different. Thus, it can be concluded that cysteamine is mainly effective on radiation-induced potentially lethal DNA lesions, and not so much on (pre)mutagenic damages. Moreover, the type of mutation appeared to be strongly dependent on the mutational target sequence.

The influence of formamidopyrimidine-DNA glycosylase on the spontaneous and γ-radiation-induced mutation spectrum of the lacZα gene

Abstract Base excision repair (BER) is a very important repair mechanism to cope with oxidative DNA damage. One of the most predominating oxidative DNA damages after exposure to ionizing radiation is 7,8-dihydro-8-oxoguanine (8oxoG). This damage is repaired by formamidopyrimidine-DNA glycosylase (Fpg), a DNA glycosylase which is part of BER. Correct repair of 8oxoG is of great importance for cells, because 8oxoG has strong miscoding properties. Mispairing of 8oxoG with adenine instead of cytosine results in G:C to T:A transversion mutations. To determine the effect of a Fpg-deficiency on the spontaneous and γ-radiation-induced mutation spectrum in the lacZ gene, double-stranded (ds) M13 DNA, with the lacZα gene inserted as mutational target, was irradiated with γ-rays in aqueous solution under oxic conditions. Subsequently, the DNA was transfected into a wild-type Escherichia coli strain (JM105) and an isogenic Fpg-deficient E. coli strain (BH410). Although the overall spontaneous mutation spectra between JM105 and BH410 seemed similar, remarkable differences could be observed when the individual base pair substitutions were viewed. The amount of C to A transversions, which are most probably caused by unrepaired 8oxoG, has increased 3.5-fold in the spontaneous BH410 spectrum. When the γ-radiation-induced mutation spectra of JM105 and BH410 were compared, there was even a larger increase of C to A transversions in the BH410 strain (7-fold). We can therefore conclude that the straightforward approach used in this study confirms the importance of Fpg in repair of γ-radiation-induced damage, and most probably especially in the repair of 8oxoG.

The role of nucleotide excision repair of Escherichia coli in repair of spontaneous and gamma-radiation-induced DNA damage in the lacZα gene

Base excision repair (BER) is a very important repair mechanism to remove oxidative DNA damage. A major oxidative DNA damage after exposure to ionizing radiation is 7,8-dihydro-8-oxoguanine (8oxoG). 8oxoG is a strong mutagenic lesion, which may cause G:C to T:A transversions if not repaired correctly. Formamidopyrimidine-DNA glycosylase (Fpg), a repair enzyme which is part of BER, is the most important enzyme to repair 8oxoG. In the past years, evidence evolved that nucleotide excision repair (NER), a repair system originally thought to repair only bulky DNA lesions, can also repair some oxidative DNA damages. Examples of DNA damages which are recognized by NER are thymine glycol and abasic sites (AP sites). The main objective of this study is to determine if NER can act as a backup system for the repair of spontaneous and gamma-radiation-induced damages when Fpg is deficient. For that purpose, the effect of a NER-deficiency on the spontaneous and gamma-radiation-induced mutation spectrum in the lacZ gene was determined, using double-stranded (ds) M13 DNA, with the lacZalpha gene inserted as mutational target sequence. Subsequently the DNA was transfected into a fpg(-)uvrA(-) Escherichia coli strain (BH420) and the mutational spectra were compared with the spectra of a fpg(-) E. coli strain (BH410) and a wild type E. coli strain (JM105), which were determined in an earlier study. Furthermore, to examine effects which are caused by UvrA-deficiency, and not by Fpg-deficiency, the spontaneous and gamma-radiation-induced mutation spectra of an E. coli strain in which only UvrA is deficient (BH430) were also determined and compared with a wild type E. coli strain (JM105). The results of this study indicate that if only UvrA is deficient, there is an increase in spontaneous G:C to T:A transversions as compared to JM105 and a decrease in A:T to G:C transitions. The gamma-radiation-induced mutation spectrum of BH420 (fpg(-)uvrA(-)) shows a significant decrease in G:C to A:T and G:C to T:A mutations, as compared to BH410 where only Fpg is deficient. Based on these results, we conclude that in our experiments NER is not acting as a backup system if Fpg is deficient. Instead, NER seems to make mistakes, leading to the formation of mutations.