Studies on the mechanisms of arsenic-induced self tolerance developed in liver epithelial cells through continuous low-level arsenite exposure.

Arsenic (As) is a human carcinogen. Our prior work showed that chronic (>18 weeks) low level (500 nM) arsenite (As3+) exposure induced malignant transformation in a rat liver epithelial cell line (TRL 1215). In these cells, metallothionein (MT) is hyper-expressible, a trait often linked to metal tolerance. Thus, this study examined whether the adverse effects of arsenicals and other metals were altered in these chronic arsenite-exposed (CAsE) cells. CAsE cells, which had been continuously exposed to 500 nM arsenite for 18 to 20 weeks, and control cells, were exposed to As3+, arsenate (As5+), dimethylarsinic acid (DMA), monomethylarsonic acid (MMA), antimony (Sb3+), cadmium (Cd2+), cisplatin (cis-Pt), and nickel (Ni2+) for 24 h and cell viability was determined by metabolic integrity. The lethal concentration for 50% of exposed cells (LC50) for As3+ was 140 microM in CAsE cells as compared to 26 microM in control cells, a 5.4-fold increase in tolerance. CAsE cells were also very tolerant to the acute toxic effects of As5+ (LC50 > 4000 microM) compared to control (LC50 = 180 microM). The LC50 for DMA was 4.4-fold higher in CAsE cells than in control cells, but the LC50 for MMA was unchanged. There was a modest cross-tolerance to Sb3+, Cd2+, and cis-Pt in CAsE cells (LC50 1.5-2.0-fold higher) as compared to control. CAsE cells were very tolerant to Ni2+ (LC50 > 8-fold higher). Culturing CAsE cells in As(3+)-free medium for 5 weeks did not alter As3+ tolerance, implicating an irreversible phenotypic change. Cellular accumulation of As was 87% less in CAsE cells than control and the accumulated As was more readily eliminated. Although accumulating much less As, a greater portion was converted to DMA in CAsE cells. Altered glutathione (GSH) levels were not linked with As tolerance. A maximal induction of MT by Zn produced only a 2.5-fold increase in tolerance to As3+ in control cells. Cell lines derived from MT normal mice (MT+/+) were only slightly more resistant (1.6-fold) to As3+ than cells from MT null mice (MT-/-). These results show that CAsE cells acquire tolerance to As3+, As5+, and DMA. It appears that this self-tolerance is based primarily on reduced cellular disposition of the metalloid and is not accounted for by changes in GSH or MT.     

Preventive mechanism of cellular glutathione in monomethylarsonic acid-induced cytolethality

Human pentavalent arsenic metabolic intermediate, monomethylarsonic acid (MMAs(V)), is a major arsenic type found in the blood in chronic arsenic poisoning patients, but little information is available on its toxicity potential or mechanisms of action. In this study, we investigated the molecular mechanisms of in vitro cytolethality of MMAs(V) using rat liver TRL 1215 cells. Cellular arsenic concentrations reached the nanomolar range in TRL 1215 cells when cells were exposed to millimolar levels of MMAs(V), and most of the MMAs(V) was not metabolized during the 48-h incubation. Under these conditions, MMAs(V) showed significant cytolethality when cellular reserves of reduced glutathione (GSH) were depleted. Morphological and biochemical evidence confirmed that MMAs(V) induced both necrosis and apoptosis in the cellular GSH-depleted cells. MMAs(V) significantly enhanced cellular caspase 3 activity in the cellular GSH-depleted cells, and a caspase 3 inhibitor blocked MMAs(V)-induced apoptosis. MMAs(V) also enhanced the production of cellular reactive oxygen species (ROS) in the cellular GSH-depleted cells, and addition of a membrane-permeable radical trapping reagent completely prevented both MMAs(V)-induced cellular caspase 3 activation and cytolethality in these cells. These observations suggest that MMAs(V) typically generates harmful ROS in cells, and cellular GSH prevents cytolethality by scavenging these toxic ROS. However, when cellular GSH levels are decreased, MMAs(V) induces oxidative stress in the cells, and this leads to apoptosis and/or necrosis depending on the cellular ROS/GSH ratio.     

Role of glutathione in dimethylarsinic acid-induced apoptosis

Inorganic arsenicals are clearly toxicants and carcinogens in humans. In mammals, including humans, inorganic arsenicals often undergo methylation, forming compounds such as dimethylarsinic acid (DMAs(V)). Recent evidence indicates that DMAs(V) is a complete carcinogen in rodents although evidence for inorganic arsenicals as carcinogens in rodents remains equivocal. Thus, we studied the molecular mechanisms of in vitro cytolethality of DMAs(V) using a rat liver epithelial cell line (TRL 1215). DMAs(V) selectively induced apoptosis in TRL 1215 cells; its LC(50) value after 48 h exposure was 4.5 mM. The addition of a glutathione synthase inhibitor, L-buthionine-[S,R]-sulfoximine (BSO), actually decreased DMAs(V)-induced apoptosis. DMAs(V) exposure temporarily decreased cellular reduced glutathione (GSH) levels and enhanced cellular glutathione S-transferase (GST) activity from 6 h after the exposure when the cells were still alive. Also, DMAs(V) exposure activated cellular caspase 3 activity with a peak at 18 h after the exposure when apoptosis began, and BSO treatment completely inhibited this enzyme activity. The additions of inhibitors of caspase 3, caspase 8, and caspase 9 significantly reduced DMAs(V)-induced apoptosis. Taken together, these data indicate that cellular GSH was required for DMAs(V)-induced apoptosis to occur, and activation of cellular caspases after conjugation of DMAs(V) with cellular GSH appears to be of mechanistic significance. Further research will be required to determine the role of intracellular GSH and methylation in the toxicity of arsenicals in chronic arsenic poisoning or in cases where arsenicals are used as chemotherapeutics.     

Further studies on aberrant gene expression associated with arsenic-induced malignant transformation in rat liver TRL1215 cells

Chronic arsenic exposure of rat liver epithelial TRL1215 cells induced malignant transformation in a concentration-dependent manner. To further define the molecular events of these arsenic-transformed cells (termed CAsE cells), gene expressions associated with arsenic carcinogenesis or influenced by methylation were examined. Real-time RT-PCR showed that at carcinogenic concentrations (500 nM, and to a less extent 250 nM of arsenite), the expressions of alpha-fetoprotein (AFP), Wilm's tumor protein-1 (WT-1), c-jun, c-myc, H-ras, c-met and hepatocyte growth factor, heme oxygenase-1, superoxide dismutase-1, glutathione-S-transferase-pi and metallothionein-1 (MT) were increased between 3 to 12-fold, while expressions of insulin-like growth factor II (IGF-II) and fibroblast growth factor receptor (FGFR1) were essentially abolished. These changes were not significant at the non-carcinogenic concentration (125 nM), except for IGF-II. The positive cell-cycle regulators cyclin D1 and PCNA were overexpressed in CAsE cells, while the negative regulators p21 and p16 were suppressed. Western-blot confirmed increases in AFP, WT-1, cyclin D1 and decreases in p16 and p21 protein in CAsE cells. The CAsE cells over-expressed MT but the demethylating agent 5-aza-deoxycytidine (5-aza-dC, 2.5 microM, 72 h) stimulated further MT expression. 5-Aza-deoxycytidine restored the loss of expression of p21 in CAsE cells to control levels, but did not restore the expression of p16, IGF-II, or FGFR1, indicating the loss of expression of these genes is due to factors other than DNA methylation changes. Overall, an intricate variety of gene expression changes occur in arsenic-induced malignant transformation of liver cells including oncogene activation and alterations in expression of genes critical to growth regulation.     

Caspase-independent apoptosis induced in rat liver cells by plancitoxin I, the major lethal factor from the crown-of-thorns starfish Acanthaster planci venom

Plancitoxin I, the major lethal factor from the crown-of-thorns starfish Acanthaster planci venom, is quite unique not only in exhibiting potent hepatotoxicity but also in sharing high sequence homology with mammalian deoxyribonulease II. In this study, morphological and biochemical changes in rat liver epithelial cells (TRL 1215 cells) treated with the toxin were examined to understand the mechanism by which plancitoxin I displays hepatotoxicity. AlamarBlue assay established that plancitoxin I is cytolethal to TRL 1215 cells. This cytolethalithy was ascribable to apoptotic cell death. Nuclear fragmentation evidenced by either Diff-Quick or Hoechst 33258 staining, DNA fragmentation by TUNEL assay and electrophoretic analysis on agarose gel and phosphatidylserine externalization by flow cytometric analysis of annexin V-FITC stained cells were all characteristics of apoptosis. The observed apoptosis was shown to be independent of the caspase 3 cascade that is generally accepted as the effector of the apoptotic process. Very interestingly, experiments using FITC-labeled plancitoxin I proved that the toxin can enter the nucleus of TRL 1215 cells. Our results suggested that plancitoxin I induces apoptosis of TRL 1215 cells through the following procedure: binding to a specific receptor in the cytoplasmic membrane, entering the cell, entering the nucleus and degrading DNA.     

A major human arsenic metabolite,dimethylarsinic acid,requires reduced glutathione to induce apoptosis

Inorganic arsenicals are important environmental toxicants and carcinogens in humans. In mammals, including humans, inorganic arsenicals often undergo methylation, forming compounds such as dimethyarsinic acid (DMA). Recent evidence indicates DMA is a complete carcinogen in rodents while evidence for inorganic arsenicals as carcinogens in rodents remains equivocal. Thus, we studied the molecular mechanisms of in vitro cytolethality of DMA compared to that of the trivalent inorganic arsenical, sodium arsenite, using a rat liver epithelial cell line (TRL 1215). Arsenite was very cytotoxic in these cells (LC(50) = 35 microM after 48 h of exposure). With arsenite exposure, most dead cells showed histological and biochemical evidence of necrosis. Arsenite cytotoxicity increased markedly when cellular GSH was depleted with the glutathione synthase inhibitor, L-buthionine-[S,R]-sulfoximine (BSO). In contrast, DMA was nearly 3 orders of magnitude less cytotoxic (LC(50) = 1.5 mM) although evidence showed the predominating form of death was apoptosis. Surprisingly, GSH depletion actually decreased DMA-induced apoptosis. A glutathione scavenger, diethyl maleate (DEM), and a glutathione reductase inhibitor, carmustine, also prevented DMA-induced apoptosis. These data indicate that DMA requires intracellular GSH to induce apoptosis. Ethacrynic acid (EA), an inhibitor of glutathione S-transferase (GST) that catalyzes GSH-substrate conjugation, acivicin, an inhibitor of gamma-glutamyltranspeptidase (GGT) which catalyzes the initial breakdown of GSH-substrate conjugates, and aminooxyacetic acid (AOAA), an inhibitor of beta-lyase which catalyzes the final breakdown of GSH-substrate conjugates, all were effective in suppressing DMA-induced apoptosis. These findings indicate that DMA likely is conjugated in some form with GSH, and that it is this conjugate that induces apoptosis during subsequent metabolic reactions.     

Cellular glutathione prevents cytolethality of monomethylarsonic acid

Inorganic arsenicals are clearly toxicants and carcinogens in humans. In mammals, including humans, inorganic arsenic often undergoes methylation, forming compounds such as monomethylarsonic acid (MMAs(V)) and dimethylarsinic acid (DMAs(V)). However, much less information is available on the in vitro toxic potential or mechanisms of these methylated arsenicals, especially MMAs(V). We studied the molecular mechanisms of in vitro cytolethality of MMAs(V) using a rat liver epithelial cell line (TRL 1215). MMAs(V) was not cytotoxic in TRL 1215 cells even at concentrations exceeding 10 mM, but it became weakly cytotoxic and induced both necrotic and apoptotic cell death when cellular reduced glutathione (GSH) was depleted with the glutathione synthase inhibitor, l-buthionine-[S,R]-sulfoximine (BSO), or the glutathione reductase inhibitor, carmustine. Similar results were observed in the other mammalian cells, such as human skin TIG-112 cells, chimpanzee skin CRT-1609 cells, and mouse metallothionein (MT) positive and MT negative embryonic cells. Ethacrynic acid (EA), an inhibitor of glutathione S-transferase (GST) that catalyses GSH-substrate conjugation, also enhanced the cytolethality of MMAs(V), but aminooxyacetic acid (AOAA), an inhibitor of beta-lyase that catalyses the final breakdown of GSH-substrate conjugates, had no effect. Both the cellular GSH levels and the cellular GST activity were increased by the exposure to MMAs(V) in TRL 1215 cells. On the other hand, the addition of exogenous extracellular GSH enhanced the cytolethality of MMAs(V), although cellular GSH levels actually prevented the cytolethality of combined MMAs(V) and exogenous GSH. These findings indicate that human arsenic metabolite MMAs(V) is not a highly toxic compound in mammalian cells, and the level of cellular GSH is critical to its eventual toxic effects.     

Suppressed oxidant-induced apoptosis in cadmium adapted alveolar epithelial cells and its potential involvement in cadmium carcinogenesis

Apoptosis involves a series of genetically programmed events associated with endonucleolytic cleavage of DNA. This process is triggered by a variety of agents, including oxidants such as hydrogen peroxide (H(2)O(2)) and it plays a key role in eliminating pre-neoplastic cells from the lung. Failure to do so could favor tumor promotion. The current study demonstrated that alveolar epithelial cells, adapted to cadmium (CdCl(2)) by repeated in vitro exposure, exhibit lower levels of H(2)O(2)-induced apoptosis than similarly challenged non-adapted cells. An immunologic assay, measuring cytoplasmic histone-associated DNA fragments, indicated maximal apoptosis 24 h after exposure to 400 microM H(2)O(2). Non-adapted cells showed a 13-fold increase in oxidant-induced apoptosis while Cd-adapted cells had only a 4-fold elevation. A terminal deoxyribonucleotidyl transferase mediated dUTP nick end labeling (TUNEL) method was used to assess the percentage of cells with DNA breaks consistent with apoptosis. Cd-adapted and non-adapted cells that were not exposed to H(2)O(2) did not differ in TUNEL positivity. However, after H(2)O(2) treatment, the percentage of TUNEL positive cells was 4-fold higher in non-adapted cultures than in adapted ones. Suppression of oxidant-induced apoptosis is due, in part, to up-regulation in the gene expression of several resistance factors including metallothioneins (MT-1 and MT-2), glutathione S-transferases (GST-alpha and GST-pi), and gamma-glutamylcysteine synthetase catalytic subunit (gamma-GCS). These steady-state mRNA changes, determined by Northern blotting, were accompanied by increased levels of MT and gamma-GCS protein, GST activity, and glutathione (GSH). Suppressed oxidant-induced apoptosis, resulting at least in part from these response modifications, could leave pre-neoplastic or neoplastic cells alive, favor clonal expansion, and ultimately lead to cancer development.     

Cyproterone acetate induces a cellular tolerance to cadmium in rat liver epithelial cells involving reduced cadmium accumulation

Several reports indicate that some steroids, in particular sex steroid hormones, can modify cadmium toxicity. We recently reported that cyproterone acetate (CA), a synthetic steroidal antiandrogen that is closely related in structure to progesterone, affects cadmium toxicity in mice. In the present study, we investigated the effect of CA on cadmium toxicity in a rat liver epithelial cell line (TRL 1215) in vitro. Cells were exposed to various concentrations of CA (0,1,10, or 50 microM) for 24 h and subsequently exposed to cadmium (0,50, or 100 microM; as CdCl2) for an additional 24 h. CA pretreatment resulted in a clear decrease in the sensitivity to cadmium. Additional time course study showed CA pretreatment provided protection against cadmium toxicity but only when given for 6 or more hours prior to cadmium exposure. Cellular cadmium accumulation was markedly reduced (60% decrease) in cells pretreated for 6 or more hours with CA. In the presence of protein synthesis inhibitors the protective effect of CA toward cadmium toxicity was abolished. However, in the presence of the GSH synthesis inhibitor, L-buthionine (S,R)-sulfoximide (BSO), the protective effect of CA toward cadmium toxicity remained. CA alone increased metallothionein (MT) levels 2.4-fold, while cadmium (50 microM) alone resulted in a 8.9-fold increase over control. However, cadmium-induced MT synthesis was markedly decreased by CA pretreatment probably because of reduced cadmium accumulation. Analysis of various metal transporters by bDNA signal amplification assay revealed that the ZnT-1 transporter gene, which encodes for a membrane protein associated with zinc efflux, was expressed three-fold more in CA treated cells than control. These data show that CA pretreatment provides protection against cadmium toxicity in vitro and indicate that this protection is due to a decreased accumulation of cadmium rather than through activation of MT synthesis. This decrease of cellular cadmium accumulation appears to be related to events that require protein synthesis and may be due to activation of the genes associated with zinc efflux.     

Effect of whey protein isolate on intracellular glutathione and oxidant-induced cell death in human prostate epithelial cells.

Cysteine is the rate-limiting amino acid for synthesis of the ubiquitous antioxidant glutathione (GSH). Bovine whey proteins are rich in cystine, the disulfide form of the amino acid cysteine. The objective of this study was to determine whether enzymatically hydrolyzed whey protein isolate (WPI) could increase intracellular GSH concentrations and protect against oxidant-induced cell death in a human prostate epithelial cell line (designated RWPE-1). Treatment of RWPE-1 cells with hydrolyzed WPI (500 microg/ml) significantly increased intracellular GSH by 64%, compared with control cells receiving no hydrolyzed WPI (P<0.05). A similar increase in GSH was observed with N-acetylcysteine (500 microM), a cysteine-donating compound known to elevate intracellular GSH. In contrast, treatment with hydrolyzed sodium caseinate (500 microg/ml), a cystine-poor protein source, did not significantly elevate intracellular GSH. Hydrolyzed WPI (500 microg/ml) significantly protected RWPE-1 cells from oxidant-induced cell death, compared with controls receiving no WPI (P<0.05). The results of this study indicate that WPI can increase GSH synthesis and protect against oxidant-induced cell death in human prostate cells.     

Rat H9c2 cardiac myocytes are sensitive to arsenite due to a modest activation of transcription factor Nrf2

The mechanism underlying the hepatotoxicity induced by arsenic exposure is well investigated. However, little is known about the detailed mechanisms of arsenic-induced cardiotoxicity or cardiac factors involved in high sensitivity to arsenicals in spite of the fact that arsenic trioxide, which is used to treat acute promyelocytic leukemia, causes cardiotoxicity. Here, we show that rat H9c2(2-1) cardiac myocytes exhibit high sensitivity to inorganic arsenite (As(III)) as compared with rat-derived four cell lines (liver epithelial TRL1215 cells, kidney epithelial NRK-52E cells, PC12 phechromocytoma cells and C6 glioma cells). Furthermore, we found a lower steady-state level of glutathione and glutamyl-cysteine ligase (GCL) in H9c2(2-1) cells compared with TRL1215 cells, resulting in an increase in arsenic accumulation. In addition, we detected that the up-regulation of GCL and multi-drug resistance-associated protein (MRP) caused by As(III) was extremely low in H9c2(2-1) cells compared with TRL1215 cells. It is known that Nrf2, which regulates GCL and MRP expression, plays an important role in the protection of cells from arsenicals. We investigated the participation of Nrf2 in the difference of sensitivity to arsenicals between H9c2(2-1) and TRL1215 cells and found that Nrf2 was clearly activated by As(III) exposure in TRL1215 cells but only poorly activated in H9c2(2-1) cells. Considering these results together, we propose that modest activation of Nrf2 during exposure to As(III) in H9c2(2-1) cardiac myocytes leads to reduced ability to metabolize and excrete arsenic.     

Enhancement of cadmium-induced metallothionein synthesis in cultured TRL 1215 cells by butyric acid pretreatment

Cultured TRL 1215 cells in log phase of growth were exposed first to butyric acid (BA; 0.1-2.0 mM) and then 48 h later, to cadmium (Cd; 10 microM). Metallothionein (MT) concentrations were measured 24 h after Cd addition. Cd alone caused approx. a 10-fold increase in cellular MT levels, while BA alone had no effect. BA pretreatment followed by Cd exposure, however, resulted in MT levels up to 25 times those in control cells. Concurrent exposure to hydroxyurea (HU) eliminated the enhancing effect of BA pretreatment on induction of MT by Cd, indicating that DNA synthesis is required. BA-pretreated cells did not show marked increases in cellular uptake of Cd. BA pretreatment enhances Cd induction of MT synthesis through a mechanism that is dependent on the synthesis of DNA.     

Toxicity of a trivalent organic arsenic compound, dimethylarsinous glutathione in a rat liver cell line (TRL 1215)

BACKGROUND AND PURPOSE: Although inorganic arsenite (As(III)) is toxic in humans, it has recently emerged as an effective chemotherapeutic agent for acute promyelocytic leukemia (APL). In humans and most animals, As(III) is enzymatically methylated in the liver to weakly toxic dimethylarsinic acid (DMAs(V)) that is a major pentavalent methylarsenic metabolite. Recent reports have indicated that trivalent methylarsenicals are produced through methylation of As(III) and participate in arsenic poisoning. Trivalent methylarsenicals may be generated as arsenical-glutathione conjugates, such as dimethylarsinous glutathione (DMAs(III)G), during the methylation process. However, less information is available on the cytotoxicity of DMAs(III)G. EXPERIMENTAL APPROACH: We synthesized and purified DMAs(III)G using high performance TLC (HPTLC) methods and measured its cytotoxicity in rat liver cell line (TRL 1215 cells). KEY RESULTS: DMAs(III)G was highly cytotoxic in TRL 1215 cells with a LC(50) of 160 nM. We also found that DMAs(III)G molecule itself was not transported efficiently into the cells and was not cytotoxic; however it readily became strongly cytotoxic by dissociating into trivalent dimethylarsenicals and glutathione (GSH). The addition of GSH in micromolar physiological concentrations prevented the breakdown of DMAs(III)G, and the DMAs(III)G-induced cytotoxicity. Physiological concentrations of normal human serum (HS), human serum albumin (HSA), and human red blood cells (HRBC) also reduced both the cytotoxicity and cellular arsenic uptake induced by exposure to DMAs(III)G. CONCLUSIONS AND IMPLICATIONS: These findings suggest that the significant cytotoxicity induced by DMAs(III)G may not be seen in healthy humans, even if DMAs(III)G is formed in the body from As(III).     

Antioxidant protection of NO-induced relaxations of the mouse anococcygeus against inhibition by superoxide anions, hydroquinone and carboxy-PTIO.

1. The potential protective effect of several antioxidants [Cu/Zn superoxide dismutase (Cu/Zn SOD), ascorbate, reduced glutathione (GSH), and alpha-tocopherol (alpha-TOC)] on relaxations of the mouse anococcygeus muscle to nitric oxide (NO; 15 microM) and, where appropriate, nitrergic field stimulation (10 Hz; 10 s trains) was investigated. 2. The superoxide anion generating drug duroquinone (100 microM) reduced relaxations to exogenous NO by 54 +/- 6%; this inhibition was partially reversed by Cu/Zn SOD (250 u ml-1), and by ascorbate (500 microM). Following inhibition of endogenous Cu/Zn SOD activity with diethyldithiocarbamate (DETCA), duroquinone (50 microM) also reduced relaxations to nitrergic field stimulation (by 53 +/- 6%) and this effect was again reversed by Cu/Zn SOD and by ascorbate. Neither GSH (500 microM) nor alpha-TOC (400 microM) afforded any protection against duroquinone. 3. Xanthine (20 mu ml-1); xanthine oxidase (100 microM) inhibited NO-induced relaxations by 73 +/- 14%, but had no effect on those to nitrergic field stimulation, even after DETCA treatment. The inhibition of exogenous NO was reduced by Cu/Zn SOD (250 u ml-1) and ascorbate (400 microM), but was unaffected by GSH or alpha-TOC (both 400 microM). 4. Hydroquinone (100 microM) also inhibited relaxations to NO (by 52 +/- 10%), but not nitrergic stimulation. In this case, however, the inhibition was reversed by GSH (5-100 microM) and ascorbate (100-400 microM), although Cu/Zn SOD and alpha-TOC were ineffective. 5. 2-(4-Carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (carboxy-PTIO, 50 microM) inhibited NO-induced relaxations by 50 +/- 4%, but had no effect on nitrergic responses; the inhibition was reduced by ascorbate (2-200 microM) and alpha-TOC (10-200 microM), but not by Cu/Zn SOD or GSH. 6. Hydroxocobalamin (5-100 microM) inhibited, equally, relaxations to both NO (-logIC40 3.14 +/- 0.33) and nitrergic stimulation (-logIC40 3.17 +/- 0.22). 7. Thus, a number of physiological antioxidants protected NO from superoxide anions, and from direct NO-scavengers. The possibility that the presence of these antioxidants within nitrergically-innervated tissues might explain the lack of effect of the NO inhibitors on nerve-induced relaxation, without the need to invoke a transmitter other than free radical NO, is discussed.     

Menadione-induced oxidative stress in hepatocytes isolated from fed and fasted rats: the role of NADPH-regenerating pathways

Isolated hepatocytes were prepared from fed and fasted rats and exposed to a range of menadione (2-methyl-1,4-naphthoquinone) concentrations. Menadione (300 microM) caused a rapid decline in the (NADPH)/(NADPH + NADP+) ratio from 0.85 to 0.39 within 15 min, with further decreases over the 90-min incubation period in cells isolated from fed animals. This decrease of NADPH resulted from oxidation to NADP+ since there was no loss of total pyridine nucleotide (NADP+ + NADPH) content. In addition, menadione (100 microM) caused a five-fold stimulation of the hexose monophosphate shunt by 30 min as indicated by the oxidation of [1-14C]glucose. LDH leakage was slightly but significantly elevated (30% of total) following exposure of cells to 300 microM menadione for 2 hr. Menadione caused a concentration-dependent GSH depletion: 100 microM menadione caused no depletion and 200 and 300 microM menadione caused a 75 and 95% decrease, respectively. Intracellular NADPH was significantly reduced within 30 min by 100 and 200 microM menadione but then returned to values equivalent to or greater than control by 60 min. In contrast, a sustained decrease of NADPH was produced by 300 microM menadione (5% of control after 2 hr). A marked potentiation of the oxidative cell injury produced by menadione was observed in hepatocytes prepared from 24-hr-fasted rats. LDH leakage was 50 and 95% when these cells were exposed to 100 and 200 microM menadione, respectively. Menadione (100 and 200 microM) also caused a marked GSH depletion (95% of control) by 90 min. In contrast to cells isolated from fed animals, menadione (100 and 200 microM) caused an 85% depletion of NADPH by 60 min in cells isolated from fasted rats. This potentiation of menadione-induced oxidative injury was not related to the decreased GSH content produced by fasting since menadione toxicity was not potentiated in control cells partially depleted of GSH by diethyl maleate. A further comparison was made between cells isolated from fasted rats and incubated either with or without supplemental glucose in order to determine a possible protective effect by glucose. In this comparison a significant (p less than 0.05) glucose effect was indeed observed in the direction of preventing GSH and NADPH depletion, as well as attenuating LDH leakage, when hepatocytes were exposed to either 50 or 100 microM menadione.(ABSTRACT TRUNCATED AT 400 WORDS)     

Modulation of thiol pools by vitamin K3 and its effect on survival of sensitive and resistant murine tumor cells.

Cytotoxic effects of vitamin K3 were evaluated utilizing the P388/S, L1210, EAT, S-180 and a multidrug-resistant variant of the P388 leukemia cells (P388/ADR). Antitumorigenic potential of vitamin K3 was assessed by MTT and DNA and RNA biosynthesis inhibition assay. A dose-dependent inhibition of P388/S and P388/ADR cell survival and [3H]thymidine and [3H]uridine incorporation (as a function of DNA and RNA biosynthesis) was observed in tumor cell types exposed to vitamin K3 concentrations ranging from 1 to 100 microM. One hundred mg/kg vitamin K3 caused a 32 and 52% increase in life span of the sensitive and resistant P388 leukemia tumor-bearing mice. Induction of DNA strand breaks at 100 microM vitamin K3 was greater in P388/S than in P388/ADR cells. In vitro treatment with vitamin K3 (100 microM) reduced the intracellular levels of GSH by 40, 47, 6, 15 and 14% in P388/S, P388/ADR, EAT, S-180 and L1210 tumor cells, respectively. In vivo treatment with 100 mg/kg vitamin K3 reduced the GSH content by 18 and 38% and increased the activity of the enzyme GSH-S-transferase and gamma-glutamyl transpeptidase. Effects of free radical scavengers and of compounds that modulate the GSH metabolism on the cytotoxicity of vitamin K3 were also investigated. Results indicate that vitamin K3 interacts with the tumor cell thiol pools while eliciting its antitumor effects and suggest the utility of vitamin K3 in dealing with the growing problem of multidrug resistance.     

Reduced cadmium-induced cytotoxicity in cultured liver cells following 5-azacytidine pretreatment

Recent work indicated that administration of the pyrimidine analog 5-azacytidine (AZA), either to cells in culture or to rats, results in an enhancement of expression of the metallothionein (MT) gene. Since MT is thought to play a central role in the detoxification of cadmium, the present study was designed to assess the effect of AZA pretreatment on cadmium cytotoxicity. Cultured rat liver cells (TRL 1215) in log phase of growth were first exposed to AZA (8 microM). Forty-eight hours later, cadmium (10 microM) was added. MT concentrations were then measured 24 hr after the addition of cadmium. A modest increase in MT amounts over control (1.7-fold) was detected after AZA treatment alone. Cadmium alone resulted in a 10-fold increase in MT concentrations. The combination of AZA pretreatment followed by cadmium exposure caused a 23-fold increase in MT concentrations over control. Treatment with the DNA synthesis inhibitor hydroxyurea (HU) eliminated the enhancing effect of AZA pretreatment on cadmium induction of MT, indicating that cell division is required. AZA-pretreated cells were also harvested and incubated in suspension with cadmium (250 microM, 37 degrees C) for 0 to 90 min. After incubation intracellular and extracellular fluids were separated by centrifugation through an oil layer. AZA-pretreated cells showed marked reductions in cadmium-induced cytotoxicity as reflected by reduced intracellular potassium loss, glutamic-oxaloacetic transaminase loss, and lipid peroxidation (assessed by thiobarbituric acid reactants) following cadmium exposure. AZA pretreatment had no effect on the cellular uptake of cadmium. Results suggest that AZA pretreatment induces tolerance to cadmium cytotoxicity which appears to be due to an increased capacity to synthesize MT rather than high quantities of preexisting MT at the time of cadmium exposure.