Radioresistance of human carcinoma cells is correlated to a defect in raft membrane clustering

In addition to DNA damage, exposure to irradiation involves the plasma membrane in the early phases of gamma-ray-induced cell death. The involvement of raft microdomains following gamma-radiation derives essentially from the role of ceramide as a critical component leading to apoptosis. It is demonstrated here that gamma-irradiation of a radiosensitive human head and neck squamous carcinoma cell line (SCC61) results in the triggering of raft coalescence to larger membrane platforms associated with the externalization of an acid sphingomyelinase (A-SMase), leading to ceramide release in raft, 30 min postirradiation. For the first time, we show that this structural rearrangement is defective in the radioresistant SQ20B cells and associated with the lack of A-SMase activation and translocation, a result which could explain in part their resistance to apoptosis following ionizing radiation. Moreover, we show that SQ20B are protected against radiation injury through a fivefold upper level of endogenous glutathione compared to SCC61. Overcoming the endogenous antioxidant defenses of SQ20B through either H(2)O(2) treatment or GSH depletion triggers A-SMase activation and translocation, raft coalescence, and apoptosis. On the contrary, ROS scavengers abolished these events in radiosensitive SCC61 cells. Translation of this concept to tumor biology suggests that manipulation of rafts through redox equilibrium may provide opportunities for radiosensitization of tumor cells.     

Transient alteration of cellular redox buffering before irradiation triggers apoptosis in head and neck carcinoma stem and non-stem cells

Background

Head and neck squamous cell carcinoma (HNSCC) is an aggressive and recurrent malignancy owing to intrinsic radioresistance and lack of induction of apoptosis. The major focus of this work was to design a transient glutathione depleting strategy during the course of irradiation of HNSCC in order to overcome their radioresistance associated with redox adaptation.

Methodology/Principal Findings

Treatment of SQ20B cells with dimethylfumarate (DMF), a GSH-depleting agent, and L-Buthionine sulfoximine (BSO), an inhibitor of GSH biosynthesis 4 h before a 10 Gy irradiation led to the lowering of the endogenous GSH content to less than 10% of that in control cells and to the triggering of radiation-induced apoptotic cell death. The sequence of biochemical events after GSH depletion and irradiation included ASK-1 followed by JNK activation which resulted in the triggering of the intrinsic apoptotic pathway through Bax translocation to mitochondria.

Conclusions

This transient GSH depletion also triggered radiation-induced cell death in SQ20B stem cells, a key event to overcome locoregional recurrence of HNSCC. Finally, our in vivo data highlight the relevance for further clinical trials of endogenous redox modulation to enhance the cytotoxic effects of radiotherapy.     

Raman Spectroscopic Study of Radioresistant Oral Cancer Sublines Established by Fractionated Ionizing Radiation

Radiotherapy is an important treatment modality for oral cancer. However, development of radioresistance is a major hurdle in the efficacy of radiotherapy in oral cancer patients. Identifying predictors of radioresistance is a challenging task and has met with little success. The aim of the present study was to explore the differential spectral profiles of the established radioresistant sublines and parental oral cancer cell lines by Raman spectroscopy. We have established radioresistant sublines namely, 50Gy-UPCI:SCC029B and 70Gy-UPCI:SCC029B from its parental UPCI:SCC029B cell line, by using clinically admissible 2Gy fractionated ionizing radiation (FIR). The developed radioresistant character was validated by clonogenic cell survival assay and known radioresistance-related protein markers like Mcl-1, Bcl-2, Cox-2 and Survivin. Altered cellular morphology with significant increase (p<0.001) in the number of filopodia in radioresistant cells with respect to parental cells was observed. The Raman spectra of parental UPCI:SCC029B, 50Gy-UPCI:SCC029B and 70Gy-UPCI:SCC029B cells were acquired and spectral features indicate possible differences in biomolecules like proteins, lipids and nucleic acids. Principal component analysis (PCA) provided three clusters corresponding to radioresistant 50Gy, 70Gy-UPCI:SCC029B sublines and parental UPCI:SCC029B cell line with minor overlap, which suggest altered molecular profile acquired by the radioresistant cells due to multiple doses of irradiation. The findings of this study support the potential of Raman spectroscopy in prediction of radioresistance and possibly contribute to better prognosis of oral cancer.     

Promoting effects of polyunsaturated fatty acids on chromosomal giant DNA fragmentation associated with cell death induced by glutathione depletion

Glutamate and buthionine sulfoximine (BSO) both reduce intracellular glutathione (GSH) concentration but by different mechanisms, and thereby induce cell death in C6 rat glioma cells. The effects of lipid peroxidation on chromosomal DNA damage during the GSH depletion-induced cell death were assessed. Polyunsaturated fatty acids (PUFA), such as arachidonic acid (AA), gamma-linolenic acid and linoleic acid enhanced lipid peroxidation, induced a loss of membrane integrity and consequently promoted 1-2 Mbp giant DNA fragmentation under both glutamate- and BSO-induced GSH-depletion. Treated C6 cells had 3'-OH termini in their DNA which were recognized by terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling (TUNEL) analysis. Antioxidants capable of scavenging reactive oxygen species and lipid radicals and iron or copper scavengers inhibited both lipid peroxidation and 1-2 Mbp giant DNA fragmentation, consequently protecting against cell death under GSH depletion. These results suggest that GSH depletion induces lipid peroxidation and leads to 1-2 Mbp giant DNA fragmentation; and that PUFAs can promote giant DNA fragmentation and 3'-OH termini in chromosomal DNA enhancing lipid peroxidation of C6 cells.     

Telomere Profiling: Toward Glioblastoma Personalized Medicine

Despite a standard of care combining surgery, radiotherapy (RT), and temozolomide chemotherapy, the average overall survival (OS) of glioblastoma patients is only 15 months, and even far lower when the patient cannot benefit from this combination. Therefore, there is a strong need for new treatments, such as new irradiation techniques. Against this background, carbon ion hadrontherapy, a new kind of irradiation, leads to a greater biological response of the tumor, while minimizing adverse effects on healthy tissues in comparison with RT. As carbon ion hadrontherapy is restricted to RT-resistant patients, photon irradiation resistance biomarkers are needed. Long telomeres and high telomerase activity have been widely associated with photon radioresistance in other cancers. Moreover, telomere protection, telomere function, and telomere length (TL) also depend on the shelterin protein complex (TRF1, TRF2, TPP1, POT1, TIN2, and hRAP1). We thus decided to evaluate an enlarged telomeric status (TL, telomerase catalytic subunit, and the shelterin component expression level) as a potential radioresistance biomarker in vitro using cellular models and ex vivo using patient tumor biopsies. In addition, nothing was known about the role of telomeres in carbon ion response. We thus evaluated telomeric status after both types of irradiation. We report here a significant correlation between TL and the basal POT1 expression level and photon radioresistance, in vitro, and a significant increase in the OS of patients with long telomeres or a high POT1 level, in vivo. POT1 expression was predictive of patient response irrespective of the TL. Strikingly, these correlations were lost, in vitro, when considering carbon irradiation. We thus propose (1) a model of the implications of telomeric damage in the cell response to both types of irradiation and (2) assessment of the POT1 expression level and TL using patient tumor biopsies to identify radioresistant patients who could benefit from carbon hadrontherapy.     

Effects of iron chelators and glutathione depletion on the induction and repair of chromosomal aberrations by tert-butyl hydroperoxide in cultured Chinese hamster cells

The effects of iron chelators and glutathione (GSH) depletion on the induction of chromosomal aberrations by tert-butyl hydroperoxide (t-BuOOH) were investigated in cultured Chinese hamster V79 cells. t-BuOOH in a concentration range of 0.1-1.0 mM induced chromosomal structural aberrations, consisting mainly of chromatid gaps and breaks, in a dose-dependent fashion. The divalent iron chelator o-phenanthroline almost completely suppressed the formation of chromosomal aberrations while the trivalent chelator desferrioxamine was less effective. GSH depletion did not affect the formation of chromosomal aberrations and DNA single-strand breaks (ssb) by t-BuOOH. DNA ssb by 0.5 mM t-BuOOH were repaired within 60 min of treatment in both GSH-depleted (GSH-) and non-depleted (GSH+) cells. In contrast, chromosomal aberrations increased a little during the 60 min after treatment in both GSH- and GSH+ cells. The aberrations were then repaired in GSH+ cells but those in GSH- cells were maintained to a great extent during 20 h of post-treatment incubation. These results indicate that divalent iron mediates the induction of chromosomal aberrations by t-BuOOH. That t-BuOOH-induced chromosomal aberrations remain even after DNA ssb were repaired suggests involvement of other lesions than DNA ssb in the formation of chromosomal aberrations by the hydroperoxide.     

Effects of glutathione on chromium‐induced DNA. Crosslinking and DNA polymerase arrest

Hexavalent chromium (Cr (VI)) is reduced intracellularly to Cr (V), Cr (IV) and Cr (III) by ascorbate (Asc), cysteine and glutathione (GSH). These metabolites induce a spectrum of genomic DNA damage resulting in the inhibition of DNA replication. Our previous studies have shown that treatment of DNA with Cr (III) or Cr (VI) plus Asc results in the formation of DNACrDNA crosslinks (CrDDC) and guaninespecific arrests of both prokaryotic and mammalian DNA polymerases. GSH not only acts as a reductant of Cr (VI) but also becomes crosslinked to DNA by Cr, thus, the focus of the present study was to examine the role of GSH in Crinduced DNA damage and polymerase arrests. Coincubation of Cr (III) with plasmid DNA in the presence of GSH led to the crosslinking of GSH to DNA. GSH cotreatment with Cr (III) also led to a decrease in the degree of Crinduced DNA interstrand crosslinks relative to Cr (III) alone, without affecting total Cr DNA binding. DNA polymerase arrests were observed following treatment of DNA with Cr (III) alone, but were markedly reduced when GSH was added to the reaction mixture. Preformed polymerasearresting lesions (CrDDC) were not removed by subsequent addition of GSH. Treatment of DNA with Cr (VI), in the presence of GSH, resulted in crosslinking of GSH to DNA, but failed to produce detectable DNA interstrand crosslinks or polymerase arrests. The inhibitory effect of GSH on Crinduced polymerase arrest was further confirmed in human genomic DNA using quantitative PCR (QPCR) analysis. Treatment of genomic DNA with Cr (III) resulted in a marked inhibition of the amplification of a 1.6 kb target fragment of the p53 gene by Taq polymerase. This was almost completely prevented by cotreatment with GSH and Cr (III). These results indicate that Crinduced DNA interstrand crosslinks, and not DNACrGSH crosslinks, are the principal lesions responsible for blocking DNA replication. Moreover, the formation of DNACrGSH crosslinks may actually preclude the formation of the polymerase arresting lesions.     

Toxicity of fotemustine in rat hepatocytes and mechanism-based protection against it

Fotemustine is a relatively novel DNA-alkylating 2-chloroethyl-substituted N-nitrosourea (CENU) drug, clinically used for the treatment of disseminated malignant melanoma in different visceral and non-visceral tissues. Thrombocytopenia has been observed in patients treated with fotemustine and liver and renal toxicities as well. In this study, firstly the metabolism of fotemustine was investigated in vitro and secondly the undesired cytotoxicity of fotemustine as well as different ways of protection against it. In rat hepatocytes, chosen as a model system, fotemustine was shown to cause lactate dehydrogenase (LDH) leakage, glutathione (GSH) depletion, GSSG-formation and lipid peroxidation (LPO). A reactive metabolite, DEP-isocyanate, is most likely responsible for these undesired cytotoxic effects. Based on the observed cytotoxicity mechanisms, chemoprotection with several sulfhydryl-containing nucleophiles and antioxidants was investigated. The sulfhydryl nucleophiles, GSH, N-acetyl-

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-cysteine (NAC) and glutathione isopropylester (GSH-IP) protected almost completely against fotemustine-induced LDH-leakage and LPO. NAC and GSH protected partly against fotemustine-induced GSH-depletion. The antioxidant, vitamin E protected completely against fotemustine-induced LPO, but only partly against fotemustine-induced LDH-leakage and not against GSH-depletion. Ebselen, a peroxidase-mimetic organoselenium compound, did not show protective effects against the cytotoxicity of fotemustine, possibly because GSH is required for the bioactivation of ebselen. It is concluded that co-administration of sulfhydryl nucleophiles, in particular NAC and GSH-IP, possibly in combination with antioxidants, such as vitamin E, are effective against the toxicity of fotemustine in vitro. It might, therefore, be worthwhile to investigate the cytoprotective potency of these agents against undesired toxicities of fotemustine in vivo as well.     

The effect of trimethylpsoralen--crosslinks on entry of donor DNA in transformation and transfection of Bacillus subtilis

Summary Transforming chromosomal DNA, irradiated with long-wave UV light in the presence of 4,5,8-trimethylpsoralen (TMP) binds to competent B. subtilis cells as effectively as non-treated DNA, but its transforming activity is strongly reduced.Uptake studies show that the entry of transforming DNA, after some stimulation by short periods of irradiation in the presence of TMP, decreases proportionally with the dose of irradiation. Crosslinking was quantitated by electron microscopy. Since the number of crosslinks increases proportionally with the dose of irradiation, it is suggested that entry of donor DNA is prevented by crosslinks. The inhibition of entry of DNA is paralleled both by decreased breakdown of crosslinked DNA interacting with competent cells, and decreased breakdown by nuclease activity liberated during protoplasting of competent cultures. These data support the model of Lacks et al. (1976) which postulates that a membrane-bound deoxyribonuclease is engaged in the entry of donor DNA into the competent cell.The transforming activity of the chloramphenicol-resistance carrying plasmid pC194, originally obtained from Staphylococcus aureus, is also destroyed by TMP crosslinks. Contrary to chromosomal DNA, its association with the cells is stimulated by longwave UV irradiation in the presence of TMP, but experiments are presented suggesting that the DNA is still vulnerable to the action of exogenous pancreatic deoxyribonuclease.Transfecting SPP1 DNA is also inactivated by TMP crosslinks. Marker rescue of transfecting DNA containing crosslinks occurs; the extent of rescue of one marker is considerably in excess of that of linked markers.     

Hypochlorous Acid Converts the ��-Glutamyl Group of Glutathione Disulfide to 5-Hydroxybutyrolactam, a Potential Marker for Neutrophil Activation

In healthy cells, glutathione disulfide (GSSG) is rapidly reduced back to glutathione (GSH) by glutathione reductase to maintain redox status. The ratio of GSH/GSSG has been used as an indicator of oxidative stress. However, hypochlorous acid (HOCl) generated by the myeloperoxidase-H₂O₂-Cl⁻ system of neutrophils converts GSH to irreversible oxidation products. Although several such products have been identified, yields of these compounds are very low in biological systems, and they cannot account quantitatively for thiol loss. In the current studies, we use liquid chromatography-mass spectrometry (LC-MS) to demonstrate that HOCl and chloramines oxidize GSSG to two irreversible products in high yield. The products, termed M-45 and M-90, are, respectively, 45 or 90 atomic mass units lighter than GSSG. The reaction pathway involves chloramine and aldehyde intermediates, and converts the γ-glutamyl residues of GSSG to 5-hydroxybutyrolactam. Importantly, M-45 and M-90 were resistant to reduction by glutathione reductase. Moreover, the monohydroxylbutyrolactam M-45 accounted for >90% of the endogenous GSH oxidation products generated by activated neutrophils. Because the reaction pathway involves chlorinating intermediates, hydroxylbutyrolactams are likely to be specific products of HOCl, which is generated only by myeloperoxidase. Therefore, our observations implicate M-45 as a potential biomarker for myeloperoxidase activity in vivo.Glutathione (GSH), a tripeptide synthesized in the cytosol from glutamate, cysteine, and glycine, is the predominant antioxidant in mammalian cells. Its concentration ranges from millimolar inside cells to micromolar in plasma (1, 2). In many cells, GSH accounts for >90% of total nonprotein thiol (3, 4). The free thiol group in GSH is responsible for biological activity. As a nucleophilic scavenger, GSH can directly react with electrophilic substances, such as reactive oxygen/nitrogen species, or be oxidized by GSH peroxidase to glutathione disulfide (GSSG). Therefore, it is essential for maintaining intracellular redox status and defending against oxidative injury. Under normal circumstances, GSSG is rapidly reduced back to GSH by glutathione reductase and NADPH. Thus, most of the GSH remains in the reduced form. Under oxidative stress, however, GSH is converted to GSSG, which potentially accumulates (2, 5). Indeed, the GSH/GSSG ratio has been used to evaluate oxidative stress in biological systems. Alterations of this ratio associate with a variety of diseases, including atherosclerosis, cancer, and human immunodeficiency virus infection (6–10).One important source of oxidative stress in humans is myeloperoxidase (MPO),² a heme protein expressed by neutrophils, monocytes, and certain populations of macrophages (11–13). Activation of these inflammatory white blood cells results in the secretion of MPO, which uses hydrogen peroxide (H₂O₂, produced by NADPH oxidase) and chloride anion to generate hypochlorous acid (HOCl) (14). HOCl rapidly reacts with a wide range of functional groups (15–19). At physiological pH, thiol groups and free amino groups are its main targets, and the initial products are oxidized thiols and chloramines.HOCl generates other products in addition to GSSG when it reacts with GSH. Chesney et al. (20) suggested that it oxidizes GSH to a higher oxidation state than the disulfide form because the molar ratio of HOCl consumed to GSH oxidized was 4:1 instead of 1:1 in Escherichia coli. Winterbourn (21) reported that approximately half of the GSH oxidized by HOCl could not be regenerated. These researchers have identified glutathione sulfonamide (GSA), glutathione thiosulfonate, and dehydroglutathione as irreversible higher oxidation products (22, 23). Their observations suggest that the formation of higher order GSSG oxidation products might account in part for the irreversible loss of GSH induced by HOCl. However, activated neutrophils (the source of MPO and therefore of HOCl) generate only low yields of these higher oxidation products, suggesting that the major products of GSH oxidation by MPO remain to be identified.The disulfide and α-amino groups of GSSG are also potential targets of HOCl (17). Disulfides can be oxidized to sulfonic acid via a sulfenyl chloride intermediate (16). α-Amino groups yield chloramines, which undergo decarboxylation, intramolecular H-abstraction, or other reaction pathways to form various products, such as aldehydes and carboxymethyllysine (16, 24). These reactions may be biologically relevant, because carboxymethyllysine production is impaired in mice deficient in the phagocyte NADPH oxidase (25). These observations suggest that GSSG is a potential scavenger of HOCl. Indeed, GSSG reportedly competes for HOCl with its rate constant expected to be 2 × 10⁵ m⁻¹ s⁻¹ (26, 27). Studies from Bast et al. (28) demonstrated that GSSG protects acetylcholinesterase from oxidative inactivation by HOCl. Nagy and Ashby (29) studied the kinetics and mechanism of GSSG oxidation by HOCl. They proposed that HOCl generates the bis-N-chloro-γ-l-glutamyl derivative of GSSG. These studies suggest that GSSG itself may function as an antioxidant.In the current study, we investigated the reaction of GSSG with HOCl and other oxidants. Using liquid chromatography in concert with mass spectrometry (LC-MS), we identified two groups of novel oxidation products, which we termed M-45 and M-90. We characterized their structures and potential reaction pathways. Our results indicate that HOCl and chloramines oxidize the γ-glutamyl moiety of GSSG to 5-hydroxybutyrolactam in high yield.     

X-ray irradiation promoted asymmetric somatic hybridisation and molecular analysis of the products

Summary Complementation of two metabolic deficiences — nitrate reductase and tryptophan synthase — was used to select for somatic fusion hybrids between tobacco (Nicotiana tabacum) and henbane (Hyoscyamus muticus) with prior X-irradiation of one partner. Using species specific, radioactively labelled DNA probes it could be shown that a) irradiation significantly reduced the amount of chromosomal DNA of the irradiated fusion partner in the somatic hybrid, b) irradiation with doses which completely inhibit protoplast division did not pevent transfer of substantial amounts of chromosomal DNA into the fusion hybrids (so called cybrids) and c) this method transfers functional nuclear genes together with the partial genome from the irradiated partner.     

Mutagenic DNA repair in Escherichia coli. VIII. Involvement of DNA polymerase III in constitutive and inducible mutagenic repair after ultraviolet and gamma irradiation.

Summary Mutagenic repair in Escherichia coli after ultraviolet (UV) irradiation has previously been shown to require a function of DNA polymerase III. In contrast, no effect of incubating a polC temperature-sensitive strain at 42° has been found after gamma irradiation. Thus at present there is no direct evidence for the involvement of polymerase III in gamma ray mutagenesis. This could, however, merely reflect the stability of the premutational lesion during the period of polymerase III insufficiency such that mutagenic repair is resumed on the plate during subsequent incubation at permissive temperature.It was previously suggested that an inducible factor might interact with polymerase III to enable it to polymerise in an error-prone way in daughter strand gaps opposite non-coding lesions in the template strand. A temperature-resistant revertant (CM 792) of a temperature-sensitive polC strain (CM 731) has been isolated which has properties expected of a strain in which the polymerase III complex is no longer susceptible to the inducible co-factor. Its UV sensitivity, spontaneous mutation rate and mutagenic response to ethyl methanesulphonate are all normal or near normal, also the rates of mutation to prototrophy after gamma irradiation and to streptomycin resistance after UV. These latter mutations are believed to arise through constitutive mutagenic repair at sites in pre-existing DNA. In contrast, the rate of UV-induced mutation to prototrophy due to changes at ochre suppressor loci is greatly depressed and no Weigle-reactivation of bacteriophage T3 is observable; both these effects are believed to result from the action of inducible mutagenic repair in newly-replicated DNA. It is suggested that the 3 to 5 exnnuclease activity of the polymerase III complex in CM 792 may not be susceptible to inhibition by an inducible factor and so continues to remove mismatched bases inserted in newly-replicated DNA opposite damage template sites thus preventing the fixation of errors as mutations.     

Survival, Deoxyribonucleic Acid Breakdown, and Synthesis in Salmonella typhimurium as Compared with Escherichia coli B Strains

Salmonella typhimurium LT-2 was compared with radioresistant (B/r) and radiosensitive (B(s-2)) strains of Escherichia coli in respect to the survival, deoxyribonucleic acid (DNA) breakdown, and DNA synthesis after X irradiation. It is shown that S. typhimurium LT-2 is about four times more sensitive than E. coli B/r but less sensitive than B(s-2). The DNA breakdown is in S. typhimurium LT-2 lower than the postirradiation breakdown of DNA in both E. coli strains and DNA synthesis proceeds in this bacterium in spite of a much lower survival, as in the radioresistant E. coli B/r.     

The Protective Role of Resveratrol in the Sodium Arsenite-Induced Oxidative Damage via Modulation of Intracellular GSH Homeostasis

Sodium arsenite (NaAsO₂) is a well-established environmental carcinogen that has been found to cause various human malignant tumors. Thus, how to prevent the deleterious effects caused by NaAsO₂ has received widely concerns. Resveratrol (3,4′,5-trihydroxystilbene), a polyphenol found in numerous plant species, has recently been known as a natural and powerful antioxidant. However, whether resveratrol could attenuate the toxicity of NaAsO₂ and its detailed mechanisms have not been reported. In this study, the protective effects of resveratrol against NaAsO₂-induced oxidative and genetic damage as well as apoptosis were evaluated for the first time. We demonstrated that cotreatment of human bronchial epithelial cell with 5 μM resveratrol for 24 h effectively reduced the levels of 30 μM NaAsO₂-induced reactive oxygen species, chromosomal and DNA damage, and cell apoptosis. Revseratrol was also showed to significantly elevate the concentration of glutathione (GSH) and the activities of its relevant enzymes as compared with NaAsO₂ alone, indicating that resveratrol ameliorates the toxicity of NaAsO₂ by modulating the process of GSH biosynthesis, recycling and utilization. Our findings further suggest that GSH homeostasis represents one of the detoxification mechanisms responding to NaAsO₂ exposure, and resveratrol plays a protective role in the regulation of oxidative and genetic damage as well as apoptosis through the modulation of GSH homeostasis.

Odd- and even-numbered medium-chained fatty acids protect against glutathione depletion in very long-chain acyl-CoA dehydrogenase deficiency

Recent trials have reported the ability of triheptanoin to improve clinical outcomes for the severe symptoms associated with long-chain fatty acid oxidation disorders, including very long-chain acyl-CoA dehydrogenase (VLCAD) deficiency.However, the milder myopathic symptoms are still challenging to treat satisfactorily. Myopathic pathogenesis is multifactorial, but oxidative stress is an important component. We have previously shown that metabolic stress increases the oxidative burden in VLCAD-deficient cell lines and can deplete the antioxidant glutathione (GSH).We investigated whether medium-chain fatty acids provide protection against GSH depletion during metabolic stress in VLCAD-deficient fibroblasts. To investigate the effect of differences in anaplerotic capacity, we included both even-(octanoate) and odd-numbered (heptanoate) medium-chain fatty acids. Overall, we show that modulation of the concentration of medium-chain fatty acids in culture media affects levels of GSH retained during metabolic stress in VLCAD-deficient cell lines but not in controls.Lowered glutamine concentration in the culture media during metabolic stress led to GSH depletion and decreased viability in VLCAD deficient cells, which could be rescued by both heptanoate and octanoate in a dose-dependent manner. Unlike GSH levels, the levels of total thiols increased after metabolic stress exposure, the size of this increase was not affected by differences in cell culture medium concentrations of glutamine, heptanoate or octanoate.Addition of a PPAR agonist further exacerbated stress-related GSH-depletion and viability loss, requiring higher concentrations of fatty acids to restore GSH levels and cell viability.Both odd- and even-numbered medium-chain fatty acids efficiently protect VLCADdeficient cells against metabolic stress-induced antioxidant depletion.     

Stable over‐expression of the 2‐oxoglutarate carrier enhances neuronal cell resistance to oxidative stress via Bcl‐2‐dependent mitochondrial GSH transport

Mitochondrial glutathione (GSH) is a key endogenous antioxidant and its maintenance is critical for cell survival. Here, we generated stable NSC34 motor neuron‐like cell lines over‐expressing the mitochondrial GSH transporter, the 2‐oxoglutarate carrier (OGC), to further elucidate the importance of mitochondrial GSH transport in determining neuronal resistance to oxidative stress. Two stable OGC cell lines displayed specific increases in mitochondrial GSH content and resistance to oxidative and nitrosative stressors, but not staurosporine. Inhibition of transport through OGC reduced levels of mitochondrial GSH and resensitized the stable cell lines to oxidative stress. The stable OGC cell lines displayed significant up‐regulation of the anti‐apoptotic protein, B cell lymphoma 2 (Bcl‐2). This result was reproduced in parental NSC34 cells by chronic treatment with GSH monoethylester, which specifically increased mitochondrial GSH levels. Knockdown of Bcl‐2 expression decreased mitochondrial GSH and resensitized the stable OGC cells to oxidative stress. Finally, endogenous OGC was co‐immunoprecipitated with Bcl‐2 from rat brain lysates in a GSH‐dependent manner. These data are the first to show that increased mitochondrial GSH transport is sufficient to enhance neuronal resistance to oxidative stress. Moreover, sustained and specific enhancement of mitochondrial GSH leads to increased Bcl‐2 expression, a required mechanism for the maintenance of increased mitochondrial GSH levels.

     

Recovery of ionizing-radiation damage after high doses of gamma ray in the hyperthermophilic archaeon Thermococcus gammatolerans

The recently discovered hyperthermophilic and radioresistant archaeon Thermococcus gammatolerans is of great interest to compare and contrast the impact of its physiology on radioresistance and its ability to repair damaged chromosomes after exposure to gamma irradiation with radioresistant bacteria. We showed that, in contrast to other organisms, cell survival was not modified by the cellular growth phase under optimal growth conditions but nutrient-limited conditions did affect the T. gammatolerans radioresistance. We determined the first kinetics of damaged DNA recovery in an archaeon after exposure to massive doses of gamma irradiation and compared the efficiency of chromosomal DNA repair according to the cellular growth phase, nutrient availability and culture conditions. Chromosomal DNA repair kinetics showed that stationary phase cells reconstitute disrupted chromosomes more rapidly than exponential phase cells. Our data also revealed that this radioresistant archaeon was proficient to reconstitute shattered chromosomes either slowly or rapidly without any loss of viability. These results suggest that rapid DNA repair is not required for the extreme radioresistance of T. gammatolerans. Angels Tapias and Christophe Leplat contributed equally to this work.     

Zinc-metallothionein genoprotective effect is independent of the glutathione depletion in HaCaT keratinocytes after solar light irradiation

UV radiations are the major environmental factors that induce DNA damage of skin cells either by direct absorption (UVB), or after inducing an oxidative stress (UVA and UVB). Cells maintain a reducing intracellular environment to avoid genomic damage. MTs have been expected not only to control metal homeostasis but also counteract the glutathione (GSH) depletion induced by oxidative stress because of their high thiol content. Induction and redistribution of MTs in cultured human keratinocytes (HaCaT) in response to SSL, is an important cellular defense mechanism against DNA damage. Reduced glutathione (GSH) is another way of cellular protection against UV-induced oxidative stress. This study which extend our previous finding focused on the relation between intracellular GSH and Zn genoprotective effects after solar irradiation. HaCaT cells, depleted or not in GSH by a chemical treatment were used to compare MTs induction by Northern blot, expression by Western blot and localization using immunocytochemistry. Zn genoprotection experiments after SSL irradiation was carried out by the comet assay. We demonstrated that in absence of GSH, Zn-MTs could protect DNA after SSL irradiation and that GSH depletion has no effect on MTs induction and localization. Nuclear Zn-MTs could be responsible for this observed genoprotection in GSH depleted cells. So the GSH/Zn and the MT/Zn systems could be two independent but interacting mechanisms of cellular protection against SSL injury.