Non-protein sulfhydryl content of Ehrlich ascites tumor cells exposed to hyperbaric oxygen or x-irradiation

Radiosensitization Efficacy of KU-2285, RP-170 and Etanidazole at Low Radiation Doses: Assessment byin VitroCytokinesis-block Micronucleus Assay

Since the cytokinesis-block micronucleus assay is very sensitive at low radiation doses, we used it to investigate the in vitro sensitizing effects of two new hypoxic cell sensitizers (KU-2285, a fluorinated 2-nitroimidazole and RP-170, a 2-nitroimidazole nucleoside analogue) at 1-3 Gy in comparison with etanidazole. Exponentially growing EMT6 cells were treated with the drugs under aerobic or hypoxic conditions for 40 min prior to and during irradiation, after which the drugs were removed and cytochalasin B (2 micrograms/ml) was added to the medium. The number of micronuclei in binucleate cells was counted after 42 h of culture. Under aerobic conditions the three compounds at 5 mM had no sensitizing effect. Under hypoxic conditions the sensitizer enhancement ratio (SER) at 5 mM was 3.8 for KU-2285, 3.2 for RP-170, and 2.3 for etanidazole, while the oxygen enhancement ratio was 2.9. When the cells were pretreated under hypoxic conditions with drugs at 5 mM but then irradiated under aerobic conditions, KU-2285 and RP-170 had a sensitizing effect whereas etanidazole did not. The sensitizers were also tested at 0.5 and 1 mM, and the SER values were compared with those obtained at high doses (15-30 Gy) using a colony assay. The SER at low doses was higher than that at high doses for 1 and 5 mM KU-2285 and 5 mM RP-170, while the SERs were similar for all concentrations of etanidazole and the lower concentrations of KU-2285 and RP-170. These results might suggest the potential usefulness of KU-2285 and RP-170 in clinical radiotherapy.

Evidences for adduct formation between intracellular non-protein thiols and nitroazoles possessing an alpha,beta-unsaturated carbonyl side chain and the effects on radiosensitization of hypoxic cells

Reactivity of a number of nitroazole derivatives bearing an alpha,beta-unsaturated carbonyl group on the side chain toward non-protein thiols (NPSH) was examined both in the phosphate buffer solution and in the biological system. These alpha,beta-unsaturated compounds reacted with NPSH, such as glutathione (GSH) and L-cysteine (Cys), in the buffer solution to afford the 1,4-addition products. The reaction gave a second-order rate constant. The adducts of methyl 4-(2'-nitroimidazol-1'-yl)crotonate (1) with GSH and Cys were isolated and characterized as two diastereomers (7a,b and 8a,b) in ca. 1:1 ratio, respectively. Similarly, exposure of EMT6/KU cells to 1 at 1.0 mM for 1 h resulted in depletion of the intracellular NPSH by more than 80%. Over 50% of the depleted NPSH was attributed to the formation of the conjugated diastereomeric adducts. On the other hand, incubation of EMT6/KU cells with 1 at 1.0 mM under hypoxic conditions before X-ray irradiation caused concurrently a sharp reduction of the shoulder of the dose-survival curves (reduced the extrapolation number (n) from 8.0 to ca. 1.0) and an increase in the slope (decreased the mean lethal dose (Do) to ca. 50% of the control level). The observed effects of 1 on the dose-survival curves were due to the NPSH depletion through the Michael addition occurred in the cellular system. A fairly linear relationship was obtained between the n value and the reduced intracellular NPSH level. It indicated that the shoulder effect of the dose-survival curves of hypoxic cells should be the result of the NPSH depletion by the alpha,beta-unsaturated carbonyl group attached to the nitroazoles.

Evaluation of various types of new hypoxic cell sensitizers using the EMT6 single cell-spheroid-solid tumour system

Eleven new hypoxic cell sensitizers representative of those developed in Japan between 1980 and 1985 were evaluated in vitro and in vivo in comparison with misonidazole (MISO), SR-2508, Ro 03-8799, and ANT (2-amino-5-nitrothiazole). The new compounds included 2-nitroimidazole nucleoside analogues, nitrotriazoles and other nitroaromatics, non-nitro compounds, and electron-affinic compounds that readily intercalate DNA. The sensitizing activity in the EMT6 single cells correlated not only with the reduction potential but, for some compounds, also with the reactivity with non-protein sulphydryls. The sensitizers were also tested using the EMT6 spheroids and solid tumours. The patterns of changes in sensitizer enhancement ratios (SERs) for single cells, spheroids, and solid tumours were classified into two types: (1) SERs for the three testing systems were similar; and (2) SERs decreased in the order of: single cells, spheroids, and solid tumours. Only nitroimidazole and nitrotriazole derivatives belonged to the former type. RK-28 and RK-29, 2-nitroimidazoles with sugar analogue components, had in vivo effects almost equal to those of MISO. Also 3- and 4-nitrotriazole derivatives had definite in vivo effects.

Chemical competition in target radical reactions: numerical simulation of the theory and comparison with measured oxygen effect on DNA damage in cells

An intracellular radiation-chemical reaction scheme is tested in which solute and solvent radicals R. react with non-target molecules Sa (scavengers) or with target molecules (presumed to be DNA) to produce target radicals T., which may also be produced by direct ionization of DNA. The rate of target radical decomposition to become 'uncommitted damage' that the cell may repair is affected by the concentration of oxygen (O2), thiols (S) and electronaffinic sensitizers (F), which compete with one another to form, respectively, target products TO2, TS and TF. This uncommitted damage is then subject to biochemical modification, including molecular repair, by the cell. The rate equations for this competing reaction scheme were written and programmed for computer simulations of changes in oxygen, thiol and electronaffinic sensitizer concentrations. A reaction scheme that also includes some non-radical target damage was also simulated. Simulations were made using available experimental data concerning intranuclear concentrations and reaction rate constants, respectively, ko, ks and k1 for the reactions T. + O2----TO2, T. + S----TS and T. + F----TF, which produce uncommitted chemical damage. Experimental data on strand-break induction in glutathione-proficient and glutathione-deficient cells, in cells treated with thiol active agents, and in cells treated with hypoxic sensitizers, along with the computer simulations, generally agree that thiol molecules can react with target radicals to reverse T. in competition with O2 and/or electronaffinic sensitizers. Forward reaction rate constants ko, ks (dithiothreitol), ks (glutathione) and k1 (misonidazole) in the approximate ratio 10:0.3:0.02:0.4 satisfied the above reaction scheme, and approximately 5 per cent non-radical target molecule damage could be included with satisfactory agreement with experimental data.