MIBG inhibits respiration: potential for radio- and hyperthermic sensitization.

INTRODUCTION: Meta-iodobenzylguanidine (MIBG) in its 131I-labeled form is clinically used as a tumor-targeted radiopharmaceutical in the diagnosis and treatment of adrenergic tumors. This well established drug may have additional clinical applications as a radiosensitizer or hyperthermic agent, ie., MIBG reportedly inhibits mitochondrial respiration in vitro. The mechanism for MIBG inhibition of cellular oxygen consumption is uncertain. Moreover, MIBG reportedly stimulates glycolysis both in vitro and in vivo. Our studies show the effect of MIBG on 9L glioma oxygen consumption and redox status with tumors cells in vitro and in vivo. MATERIALS AND METHODS: The effects on electron transfer were determined by following oxygen consumption with a Clark oxygen electrode. Fluorescence measurements were used to determine effects of MIBG on intracellular electron acceptors, NADPH and flavoproteins, in vitro and in vivo. 31P-NMR was used to determine alterations in tumor cell pH in vivo. RESULTS: Our results show the inhibition of oxygen utilization with MIBG for cell suspensions in vitro. The same results were demonstrated for tumor cell suspensions rapidly isolated from tumors grown in rats. Moreover, NAD(P)H and flavoprotein (Fp) fluorescence changes were observed to rapidly occur following MIBG addition in vitro. Changes in intracellular pH measured with 31P-NMR, in vivo, precede the changes in fluorescence of NAD(P)H and Fp obtained with frozen sections of tumor. CONCLUSIONS: We conclude that 31P-NMR measurements and fluorescence changes, following MIBG injection, can be used as criterion for selecting the proper time to treat tumors with ionizing radiation or hyperthermia.

Selenium and vitamin E inhibit radiogenic and chemically induced transformation in vitro via different mechanisms.

Results from in vivo and in vitro studies showing that antioxidants may act as anticarcinogens support the role of active oxygen in carcinogenesis and provide impetus for exploring the functions of dietary antioxidants in cancer prevention by using in vitro models. We examined the single and combined effects of selenium, a component of glutathione peroxidase, and vitamin E, a known antioxidant, on cell transformation induced in C3H/10T-1/2 cells by x-rays, benzo[a]pyrene, or tryptophan pyrolysate and on the levels of cellular scavenging systems and peroxide destruction. Incubation of C3H/10T-1/2 cells with 2.5 microM Na2SeO3 (selenium) or with 7 microM alpha-tocopherol succinate (vitamin E) 24 hr prior to exposure to x-rays or the chemical carcinogens resulted in an inhibition of transformation by each of the antioxidants with an additive-inhibitory action when the two nutrients were combined. Cellular pretreatment with selenium resulted in increased levels of cellular glutathione peroxidase, catalase, and nonprotein thiols (glutathione) and in an enhanced destruction of peroxide. Cells pretreated with vitamin E did not show these biochemical effects, and the combined pretreatment with vitamin E and selenium did not augment the effect of selenium on these parameters. The results support our earlier studies showing that free radical-mediated events play a role in radiation and chemically induced transformation. They indicate that selenium and vitamin E act alone and in additive fashion as radioprotecting and chemopreventing agents. The results further suggest that selenium confers protection in part by inducing or activating cellular free-radical scavenging systems and by enhancing peroxide breakdown while vitamin E appears to confer its protection by an alternate complementary mechanism.

Factors influencing the oxidation of cysteamine and other thiols: implications for hyperthermic sensitization and radiation protection.

Some of the factors influencing the oxygen uptake and peroxide formation for cysteamine (MEA) and other thiols in serum-supplemented modified McCoy's 5A, a well-known medium used to cultivate a variety of cells in vitro, have been studied. The oxidation of MEA and cysteine in modified McCoy's 5A has been compared with that in Ham's F-12, MEM, and phosphate-buffered saline. All of the growth media were supplemented with 10% calf serum and 5% fetal calf serum. The rate of oxygen uptake for all of the studied thiols was greatest in McCoy's 5A. The data indicate that this medium may contain more copper than the other preparations. MEA and cysteine were found to be more effective at 0.4 mM at producing peroxide than dithiothreitol (DTT). N-acetylcysteine was the least reactive. The ability to produce peroxide is dependent upon the temperature, the concentration of thiol, the presence of copper ions, and pH of the medium. MEA and other thiol oxidation is inhibited by the copper chelator diethyldithiocarbamate. Catalase also reduces the oxygen uptake for all thiols. This inhibition involves the recycling of peroxide to oxygen. Superoxide dismutase (SOD) was found to stimulate the oxygen uptake in the case of MEA and cysteine, but had little or no effect with DTT and glutathione. The combined presence of SOD and catalase resulted in less inhibition of oxygen uptake than that obtained by catalase alone. Alkaline pH was found to enhance the oxidation of cysteine and MEA. An important observation was the inhibition of MEA oxidation at 0 degrees C and the stimulation at 42 degrees C. The results indicate that many problems may arise when thiols are added to various media. A major consideration is concerned with the production of peroxide, superoxide, and reduced trace metal intermediates. The presence of these intermediates may result in the production of hydroxyl radical intermediates as well as the eventual oxygen depletion from the medium. Oxygen depletion may alter the results of radiation sterilization and carcinogen activation. Radical production will cause cell damage that is temperature dependent. Therefore, careful consideration must be given to changes in oxygen tension when thiols are added to cells growing in complicated growth medium to protect against either chemical or radiation damage.

Factors associated with the preincubation effect of hypoxic cell sensitizers in vitro and their possible implications in chemosensitization.

The enhancement of melphalan toxicity was observed by preincubation of V-79- 379A cells in spinner culture with multiple doses of misonidazole (miso) or SR-2508 under hypoxic conditions. Chemosensitization was shown to be a function of sensitizer concentration and duration of exposure to the alkylating agent. A preincubation exposure of cells with 5 mM miso reduced endogenous cell thiols to less than 5% of controls and enhanced melphalan toxicity by a factor of 4.7. Cells preincubated with miso not only had lower levels of nonprotein thiols, but also were shown to have altered levels of intracellular calcium and a lower threshold to oxidative stress as measured by toxicity to cysteamine or H2O2. Preincubated cells, hypoxic cells, and cells receiving moderate hyperthermia (42.5 degrees C for 3 hr) all showed increased sensitivity to either cysteamine or H2O2. The increased killing of preincubated cells by cysteamine was shown to be similar to that of H2O2, and the dramatic reduction of cysteamine toxicity by catalase indicated H2O2 was the major reaction associated with this effect. These results indicate that preincubated cells exhibit a variety of biological effects that may significantly influence their response to further treatment with drugs or radiation, especially where peroxidative and free radical mechanisms are involved. The depletion of endogenous thiols, calcium disturbance, and vulnerability to oxidative stress are factors to be considered when interpreting mechanisms of combined drug action and effects that may potentially be exploited in terms of therapeutic gains.

On the mechanism for enhancement of tumor radiation to hyperbaric oxygen in sodium pentobarbital anesthetized rodents.

Pentobarbital anesthesia has been observed to increase markedly the effectiveness of respiration of oxygen at 3 atmospheres of pressure absolute to increase the response of early generation isotransplants of C3H mouse tumors to two-dose irradiation. A possible mechanism of this phenomenon is suppression of oxygen utilization by the pentobarbital and hence increasing mean pO2 and oxygen diffusion lengths. Measurements of QO2 of suspension of MCaIV and FSaII cells from freshly excised tumor tissue have been measured for cells suspended in PBS, Hank's buffered with HEPES +/- glutamate. The oxygen utilization by these tumor cells in vitro (when measured at congruent to 10 minutes after excision) is low, viz. 1 nmole/min/mg protein as compared with 6-9 nmoles/min/mg protein for established cell lines cultured in vitro. The suppression of QO2 by 2mM pentobarbital is less than 10%. This is a concentration of pentobarbital that is judged to be close to that which obtains in the tissues of the animals in the radiation response assays. Pentobarbital at .2mM did not change the cell survival characteristics of Chinese V79 cell spheroids irradiated in vitro. The results of these experiments do not indicate the suppression of oxygen utilization is an important contributor to the observed phenomenon of the increased response of tumors irradiated in mice respiring oxygen at high pressure. The role of hypothermia produced by the anesthesia is under further study.

Newly synthesized hypoxia-mediated drugs as radiosensitizers and cytotoxic agents.

Chinese hamster cells in culture were used to compare the radiosensitizing efficiency and cytotoxicity of misonidazole with several 2, 4 and 5 substituted nitroimidazoles. The two substituted compounds (SR 2508 and SR 2555) are similar to misonidazole in radiosensitizing effectiveness, but are significantly less toxic to hypoxic cells. This reduced cytotoxicity may result from either slower drug penetration or slower removal of non-protein sulfhydryl compounds (NPSH). The compound MJL-1-191-VII (a 4-nitroimidazole) is a much more effective radiosensitizer than would be predicted from its electron affinity. It appears to sensitize by two mechanisms, the first resulting from its electron affinity and the second as consequence of its rapid removal of endogeneous cellular NPSH; which are naturally occurring radioprotective substances.