Iraimoudi S. Ayene

Detection of Reactive Oxygen Species via Endogenous Oxidative Pentose Phosphate Cycle Activity in Response to Oxygen Concentration IMPLICATIONS FOR THE MECHANISM OF HIF-1α STABILIZATION UNDER MODERATE HYPOXIA

The oxidative pentose phosphate cycle (OPPC) is necessary to maintain cellular reducing capacity during periods of increased oxidative stress. Metabolic flux through the OPPC increases stoichiometrically in response to a broad range of chemical oxidants, including those that generate reactive oxygen species (ROS). Here we show that OPPC sensitivity is sufficient to detect low levels of ROS produced metabolically as a function of the percentage of O2. We observe a significant decrease in OPPC activity in cells incubated under severe and moderate hypoxia (ranging from <0.01 to 4% O2), whereas hyperoxia (95% O2) results in a significant increase in OPPC activity. These data indicate that metabolic ROS production is directly dependent on oxygen concentration. Moreover, we have found no evidence to suggest that ROS, produced by mitochondria, are needed to stabilize hypoxia-inducible factor 1α (HIF-1α) under moderate hypoxia. Myxothiazol, an inhibitor of mitochondrial electron transfer, did not prevent HIF-1α stabilization under moderate hypoxia. Moreover, the levels of HIF-1α that we observed after exposure to moderate hypoxia were comparable between ρ0 cells, which lack functional mitochondria, and the wild-type cells. Finally, we find no evidence for stabilization of HIF-1α in response to the non-toxic levels of H2O2 generated by the enzyme glucose oxidase. Therefore, we conclude that the oxygen dependence of the prolyl hydroxylase reaction is sufficient to mediate HIF-1α stability under moderate as well as severe hypoxia.

Ku protein targeting by Ku70 small interfering RNA enhances human cancer cell response to topoisomerase II inhibitor and γ radiation

Ku protein is a heterodimer (Ku70 and Ku86) known to play an important role in V(D)J recombination, apoptosis, telomere fusion, and double-strand break repair. Its role in double-strand breaks is relevant to cancer therapy because lack of Ku86 causes one of the most radiation-responsive phenotypes (hamster cells, XRS5). Although it is known that the heterodimer is necessary for the various functions of this protein, the impact of targeting Ku in human cancer cells has not been shown due to lack of appropriate approaches. It is also not known whether complete knock-out of Ku protein is required to enhance the sensitivity of human cells to γ radiation as Ku protein is much more abundant in human cells than in hamster cells. In the current article, we have investigated the direct effect of Ku70 depletion in human cervical epithelioid (HeLa) and colon carcinoma (HCT116) cells. We specifically targeted Ku70 mRNA by use of small interfering RNA (siRNA). Of the five Ku70 siRNA synthesized, three inhibited the expression of Ku70 by up to 70% in HeLa cells. We have tested the effect of chemically synthesized siRNAs for target sequence 5 (CS #5) on the response of HeLa cells 72 hours after transfection to γ radiation and etoposide, as this showed the maximum inhibition of Ku70 expression. Ku70 siRNA induced a decrease in the surviving fraction of irradiated HeLa cells by severalfold. Similar sensitizing effects were observed for etoposide, a topoisomerase II inhibitor. Studies with HCT116 cells using the same Ku70 siRNA (CS #5) showed a direct correlation between expression of Ku70 and sensitization to radiation and etoposide treatments.

Mutation in the Glucose-6-phosphate Dehydrogenase Gene Leads to Inactivation of Ku DNA End Binding during Oxidative Stress

Glucose-6-phosphate dehydrogenase (G6PD), the rate-limiting enzyme of the oxidative pentose phosphate cycle, regulates the NADPH/NADP+ ratio in eukaryotic cells. G6PD deficiency is one of the most common mutations in humans and is known to cause health problems for hundreds of millions worldwide. Although it is known that decreased G6PD functionality can result in increased susceptibility to oxidative stress, the molecular targets of this stress are not known. Using a Chinese hamster ovary G6PD-null mutant, we previously demonstrated that exposure to a thiol-specific oxidant, hydroxyethyldisulfide, caused enhanced radiation sensitivity and an inability to repair DNA double strand breaks. We now demonstrate a molecular mechanism for these observations: the direct inhibition of DNA end binding activity of the Ku heterodimer, a DNA repair protein, by oxidation of its cysteine residues. Inhibition of Ku DNA end binding was found to be reversible by treatment of the nuclear extract with dithiothreitol, suggesting that the homeostatic regulation of reduced cysteine residues in Ku is a critical function of G6PD and the oxidative pentose cycle. In summary, we have discovered a new layer of DNA damage repair, that of the functional maintenance of repair proteins themselves. In view of the rapidly escalating number of roles ascribed to Ku, these results may have widespread ramifications.

Radiation Response of Cells during Altered Protein Thiol Redox

Abstract Biaglow, J. E., Ayene, I. S., Koch, C. J., Donahue, J., Stamato, T. D., Mieyal, J. J. and Tuttle, S. W. Radiation Response of Cells during Altered Protein Thiol Redox. Radiat. Res. 159, 484–494 (2003). The major focus of this work was to investigate how altered protein thiol redox homeostasis affects radiation-induced cell death. We used the cells of wild-type CHO cell line K1, the CHO cell line E89, which is null for G6PD activity, and a radiation-sensitive CHO cell line, XRS5. The protein-thiol redox status of cells was altered with cell-permeable disulfides, hydroxyethyldisulfide (HEDS) or lipoate. HEDS is primarily reduced by thioltransferase (glutaredoxin), with GSH as the electron donor. In contrast, lipoate is reduced by thioredoxin reductase. HEDS was reduced at a greater rate than lipoate by G6PD-containing K1 (wild-type) cells. Reduction of disulfides by G6PD-deficient cells was significantly slower with HEDS as substrate and was nearly absent with lipoate. The rate of reduction of HEDS by E89 cells decelerated to near zero by 30 min, whereas the reduction continued at nearly the same rate during the entire measurement period for K1 cells. HEDS treatment decreased the GSH and protein thiol (PSH) content more in G6PD-deficient cells than in G6PD-containing cells. On the other hand, lipoate did not significantly alter the protein thiol, but it increased the GSH in K1 cells. Acute depletion of GSH by l-buthionine-sulfoximine (l-BSO) in combination with dimethylfumarate significantly decreased the rate of reduction of HEDS by K1 cells close to that of G6PD-deficient cells. Prior GSH depletion by l-BSO alone significantly decreased the PSH in glucose-depleted E89 cells exposed to HEDS, but this did not occur with K1 cells. The radiation response of G6PD-deficient cells was significantly sensitized by HEDS, but HEDS did not have this effect on K1 cells. The DNA repair-deficient XRS5 CHO cells displayed the same capacity as K1 cells for HEDS reduction, and like K1 cells the XRS5 cells were not sensitized to radiation by HEDS treatment. Deprivation of glucose, which provides the substrate for G6PD in the oxidative pentose phosphate cycle, decreased the rate of bioreduction of HEDS and lipoate in G6PD-containing cells to the level in G6PD-deficient cells. In the absence of glucose, HEDS treatment diminished non-protein thiol and protein thiol to the same level as those in G6PD-deficient cells and sensitized the K1 cells to HEDS treatment. However, depletion of glucose did not alter the sensitivity of XRS5 cells in either the presence or absence of HEDS. Overall the results suggest a major role for pentose cycle control of protein redox state coupled to the activities of the thioltransferase and thioredoxin systems. The results also show that protein thiol status is a critical factor in cell survival after irradiation.

Oxidation of cellular thiols by hydroxyethyldisulphide inhibits DNA double-strand-break rejoining in G6PD deficient mammalian cells

Purpose : We investigated the effect of protein- and non proteinthiol oxidation on DNA double-strand-break (DSB) rejoining after irradiation and its relevance in the survival of CHO cells. Materials and methods : We used mutant cells null for glucose 6 phosphate dehydrogenase (G6PD) activity since reducing equivalents, required for reduction of oxidized thiols, are typically generated through G6PD regulated production of NADPH. Cellular thiols were oxidized by pre-incubating the cells with hydroxyethyldisulphide (HEDS), the oxidized form of mercaptoethanol (ME). The concentrations of the intracellular and extracellular non-protein thiols (NPSH), glutathione, cysteine and mercaptoethanol were quantitated by HPLC. Protein thiols (PSH) were estimated using Ellmans reagent. Cell survival was determined by clonogenic assay. The induction and rejoining of DSB in cells was quantitated by Pulse Field Gel Electrophoresis after exposure to ionizing radiation. Results : Much lower bioreduction of HEDS was found in the G6PD deficient mutants (E89) than in the wild-type cells (K1). A 1 h treatment of E89 cells with HEDS produced almost complete depletion of non-protein thiol (NPSH) and a 26% decrease in protein thiols. Only minor changes were found under similar conditions with K1 cells. When exposed to gamma radiation in the presence of HEDS, the G6PD null mutants exhibited a higher cell killing and decreased rate and extent of rejoining of DSB than were observed in K1 cells. Moreover, when the G6PD deficient cells were transfected with the gene encoding wild-type G6PD (A1A), they recovered close to wild-type cellular thiol status, cell survival and DSB rejoining. Conclusions : These results suggest that a functioning oxidative pentose phosphate pathway is required for DSB rejoining in cells exposed to a mild thiol oxidant.PURPOSE We investigated the effect of protein- and non protein-thiol oxidation on DNA double-strand-break (DSB) rejoining after irradiation and its relevance in the survival of CHO cells. MATERIALS AND METHODS We used mutant cells null for glucose 6 phosphate dehydrogenase (G6PD) activity since reducing equivalents, required for reduction of oxidized thiols, are typically generated through G6PD regulated production of NADPH. Cellular thiols were oxidized by pre-incubating the cells with hydroxyethyldisulphide (HEDS), the oxidized form of mercaptoethanol (ME). The concentrations of the intracellular and extracellular non-protein thiols (NPSH), glutathione, cysteine and mercaptoethanol were quantitated by HPLC. Protein thiols (PSH) were estimated using Ellmans reagent. Cell survival was determined by clonogenic assay. The induction and rejoining of DSB in cells was quantitated by Pulse Field Gel Electrophoresis after exposure to ionizing radiation. RESULTS Much lower bioreduction of HEDS was found in the G6PD deficient mutants (E89) than in the wild-type cells (K1). A 1 h treatment of E89 cells with HEDS produced almost complete depletion of non-protein thiol (NPSH) and a 26% decrease in protein thiols. Only minor changes were found under similar conditions with K1 cells. When exposed to gamma radiation in the presence of HEDS, the G6PD null mutants exhibited a higher cell killing and decreased rate and extent of rejoining of DSB than were observed in K1 cells. Moreover, when the G6PD deficient cells were transfected with the gene encoding wild-type G6PD (A1A), they recovered close to wild-type cellular thiol status, cell survival and DSB rejoining. CONCLUSIONS These results suggest that a functioning oxidative pentose phosphate pathway is required for DSB rejoining in cells exposed to a mild thiol oxidant.

Role of vicinal protein thiols in radiation and cytotoxic responses

Abstract Biaglow, J. E., Ayene, I. S., Tuttle, S. W., Koch, C. J., Donahue, J. and Mieyal, J. J. Role of Vicinal Protein Thiols in Radiation and Cytotoxic Responses. Radiat. Res. 165, 307–317 (2006). Glutathione (GSH) and more recently protein thiols (P-SH) have been found to play a major role in cellular radiation response. However, the effects of protein vicinal thiols, which are important for the functions of several major enzymes, on cellular responses to radiation have not been clearly delineated. Here we investigated the effects of depleting GSH and protein vicinal thiols (HS-P-SH) and P-SH on cell toxicity and radiation response. We used hydroxyethyldisulfide (HEDS, β-mercaptoethanol-disulfide) alone and in combination with phenylarsine oxide (PAO) to alter P-SH, HS-P-SH and GSH. HEDS, a direct substrate for thioredoxin reductase and an indirect substrate for glutaredoxin (thioltransferase), did not alter protein vicinal thiols in cells. However, PAO, which specifically forms a covalent adduct with vicinal thiols, blocked bioreduction of HEDS; there was a concomitant and yet unexplained decrease in K1 cell GSH in the presence of HEDS and PAO. G6PD+ (K1) and G6PD− (E89) cells treated with l-buthionine sulfoximine (l-BSO) for 72 h to deplete GSH followed by PAO showed an increased cytotoxic response. However, the surviving E89 cells showed a 10,000-fold greater radiation lethality than the K1 cells. The effects of rapid depletion of GSH by a combination of l-BSO and dimethyfumarate (DMF), a glutathione-S-transferase substrate, were also investigated. Under these conditions, PAO radiosensitized the E89 cells more than 1000-fold over the K1 cells. The potential mechanisms for the altered response may be related to the inhibition of thioredoxin reductase and glutaredoxin. Both are key enzymes involved in DNA synthesis, protein homeostasis and cell survival. With GSH removed, vicinal thiols appear to play a critical role in determining cell survival and radiosensitivity. Decreasing P-SH and removing GSH and vicinal thiols is extremely toxic to K1 and E89 cells. We conclude that radiation sensitivity and cell survival are dependent on vicinal thiol and GSH. In the former and latter cases, the protein thiols are also important.

DNA strand breakage by bivalent metal ions and ionizing radiation

Purpose: To investigate mechanisms of DNA breakage via the interaction of bivalent metal ion, thiol reducing agent and ionizing radiation, in •OH scavenging abilities comparable to those in cells. Materials and methods: We measured the effects of 10 min exposure to 200 μM Fe2+ vs. Fe3+ on the induction of single (SSB) and double (DSB) strand breaks in unirradiated and oxically irradiated SV40 DNA, in aqueous solution containing 75 or 750 mM glycerol and/or 5 mM glutathione (GSH). Results: Fe2+ or GSH alone produced little DNA damage. However, their combination produced a dramatic increase in the production of both SSB and DSB. Experiments with ferric ion suggest that it produces DNA damage only after partial reduction to ferrous by GSH. Induction efficiencies for SSB in the presence of Fe2+/GSH showed additivity of the effects of radiation alone with those from Fe2+/GSH. However, the corresponding induction efficiencies for DSB demonstrated a 2.5-fold enhancement. Conclusions: Our results are consistent with a model in which reduced bivalent metal ions plus thiols, in the presence of O2, produce DSB in DNA primarily via local clusters of hydroxyl radicals arising from site specific Fenton reactions. The synergism observed between DSB production by Fe/GSH and by ionizing radiation, also believed to occur via local clusters of hydroxyl radicals, is consistent with this model. Our results suggest that both normally present intracellular iron and ionizing radiation may be important sources of oxidative stress in cells.

Modification of Radiation-Induced Strand Breaks by Glutathione: Comparison of Single- and Double-Strand Breaks in SV40 DNA

A number of investigations have suggested that the widely observed oxygen enhancement of radiation-induced cell killing or intracellular DNA damage requires the presence of glutathione (GSH) or other thiols. We have adapted an in vitro model system to investigate the effects of GSH on radiation-induced DNA double-strand breaks (DSBs), lesions felt to be critical to cell death. Superhelical SV40 DNA, 25 micrograms/ml, was irradiated in air or nitrogen in the presence of 0-20 mM GSH and single-strand breaks (SSBs) and DSBs were measured using neutral gel electrophoresis/ethidium bromide fluorescence. Control experiments demonstrated that a substantial concentration of free SH was still present after irradiation. Dose-response curves for SSBs and DSBs in air or nitrogen were predominantly linear at all GSH concentrations tested from 0-20 mM, except for 20 mM GSH in nitrogen, indicating that both SSB and DSB formation are predominantly by one-hit mechanisms under these conditions. Dose-response curves for both SSBs and DSBs in nitrogen at 20 mM GSH closely tracked the corresponding linear curves in air for doses up to about 200 Gy, then reached a plateau at higher doses. Induction efficiencies in 20 mM GSH, calculated from these initial slopes for both SSBs and DSBs in nitrogen, were unexpectedly higher than the corresponding efficiencies in 5 mM GSH, suggesting additional damage, rather than the expected additional protection. The possible mechanism for a damaging effect from GSH is discussed. Oxygen enhancement ratios (OERs) were calculated from the slopes of dose-response curves. The OERs for SSBs did not differ substantially from those for DSBs at the same [GSH], contrary to the observations of Prise et al. (Radiat. Res. 134, 102-106, 1993). The OERs for SSBs and DSBs peaked at 6.5 and 8, respectively, at 5 mM GSH. These similarities suggest that the much lower OERs (2.5-3.0) generally reported for radiation killing of cells, which also typically contain about 5 mM GSH, cannot be accounted for by differences in OER between lethal lesions, represented by DSBs, and nonlethal lesions, represented by SSBs. In view of the present results, another possible explanation, that intracellular compounds other than reduced thiols are important in the chemical modification of the response of DNA to radiation, seems to be much more likely.

DNA as an important target in radiation-induced apoptosis of MYC and MYC plus RAS transfected rat embryo fibroblasts

PURPOSE This study uses a radiation chemistry approach to determine if DNA is an important target for radiation-induced apoptosis of myc (MR4) and myc plus ras (3.7) transfected rat embryo fibroblast cell lines. MATERIALS AND METHODS The radiation protection efficiency of four thiols was compared with net molecular charge ranging from -1 to +2: mercaptopropionic acid (Z= -1), mercaptoethanol (Z=0), cysteamine (Z= +1), N(2-mercaptoethyl)-1,3-diaminopropane (Z= +2). Protection factors were determined for these thiols against radiation-induced apoptosis (Apoalert assay), mitotic cell death (clonogenic assay) and double-strand break (dsb) induction (pulse field gel electrophoresis) in MR4 and 3.7 cells. Theoretical protection factors for these thiols against dsb induction were also calculated from second-order chemical repair constants for single-strand breaks (ssb) and the concentration of added thiols in MR4 and 3.7 cell lines. RESULTS The charge-dependent increases observed for measured protection factors against radiation-induced apoptosis did not differ significantly between the two cell lines, nor did they differ significantly from the corresponding increases observed for radiation-induced mitotic cell killing and for induction of dsb. The calculated protection factor for dsb also showed a thiol charge-dependent increase similar to the measured protection factors for all of the other parameters studied. CONCLUSIONS These results are consistent with the hypothesis that DNA is an important target for radiation-induced apoptosis.Purpose : This study uses a radiation chemistry approach to determine if DNA is an important target for radiation-induced apoptosis of myc (MR4) and myc plus ras (3.7) transfected rat embryo fibroblast cell lines. Materials and methods : The radiation protection efficiency of four thiols was compared with net molecular charge ranging from -1 to +2: mercaptopropionic acid (Z = -1), mercaptoethanol (Z = 0), cysteamine (Z = +1), N(2-mercaptoethyl)-1,3-diaminopropane (Z = +2). Protection factors were determined for these thiols against radiation-induced apoptosis (Apoalert assay), mitotic cell death (clonogenic assay) and double-strand break (dsb) induction (pulse field gel electrophoresis) in MR4 and 3.7 cells. Theoretical protection factors for these thiols against dsb induction were also calculated from second-order chemical repair constants for single-strand breaks (ssb) and the concentration of added thiols in MR4 and 3.7 cell lines. Results : The charge-dependent increases observed for measured protection factors against radiation-induced apoptosis did not differ significantly between the two cell lines, nor did they differ significantly from the corresponding increases observed for radiation-induced mitotic cell killing and for induction of dsb. The calculated protection factor for dsb also showed a thiol charge-dependent increase similar to the measured protection factors for all of the other parameters studied. Conclusions : These results are consistent with the hypothesis that DNA is an important target for radiation-induced apoptosis.

The measurement of bioreductive capacity of tumor cells using methylene blue

PURPOSE Methylene blue (MB) can be used as an intracellular electron acceptor. The purpose of this study was to demonstrate the usefulness of MB for the determination of total bioreductive capacity of cell suspensions. METHODS AND MATERIALS We measured oxygen consumption by Clark electrode and pentose cycle activity by release of 14CO2 from 1-14C-glucose. RESULTS Methylene blue catalyzes the reaction of intracellular reductants NADPH, NADH, and reduced glutathione (GSH) with oxygen, causing the production of hydrogen peroxide. The reaction rate correlates with the negative charge of molecule (NADPH(-4) > NADH(-2) > GSH(-1)), suggesting that reaction with positively charged oxidized MB is the limiting step of the reaction. In a cellular system MB causes the electron flow from cellular endogenous substrates to oxygen. It is activated by the disruption of the NADP+/NADPH ratio due to several processes. These are direct oxidation of NADPH and GSH, the GSH peroxidase catalyzed reaction of GSH with H2O2, followed by NADPH oxidation by oxidized glutathione (GSSG). This results in increased cellular oxygen consumption and stimulation of the oxidative limb of pentose cycle (PC) in the presence of MB. The cellular effect of MB differs from other electron accepting drugs. Diamide and tert-butylhydroperoxide act as direct oxidants, while MB is an electron carrier to oxygen. Accordingly, MB shows the highest effect on PC activation and oxygen consumption. CONCLUSIONS Our results indicate that MB may be used for the determination of the total bioreductive capacity of the cells, measured by oxygen consumption and PC activation.