Metabolic activation of 3-hydroxyanisole by isolated rat hepatocytes

A tyrosinase-directed therapeutic approach for malignant melanoma therapy uses the depigmenting phenolic agents such as 4-hydroxyanisole (4-HA) to form cytotoxic o-quinones. However, renal and hepatic toxicity was reported as side effects in a recent 4-HA clinical trial. In search of novel therapeutics, the cytotoxicity of the isomers 4-HA, 3-HA and 2-HA were investigated. In the following, the order of the HAs induced hepatotoxicity in mice, as measured by increased in vivo plasma transaminase activity, or in isolated rat hepatocytes, as measured by trypan blue exclusion, was 3-HA > 2-HA > 4-HA. Hepatocyte GSH depletion preceded HA induced cytotoxicity and a 4-MC-SG conjugate was identified by LC/MS/MS mass spectrometry analysis when 3-HA was incubated with NADPH/microsomes/GSH. 3-HA induced hepatocyte GSH depletion or GSH depletion when 3-HA was incubated with NADPH/microsomes was prevented by CYP 2E1 inhibitors. Dicumarol (an NAD(P)H: quinone oxidoreductase inhibitor) potentiated 3-HA- or 4-methoxycatechol (4-MC) induced toxicity whereas sorbitol (an NADH generating nutrient) greatly prevented cytotoxicity indicating a quinone-mediated cytotoxic mechanism. Ethylendiamine (an o-quinone trap) largely prevented 3-HA and 4-MC-induced cytotoxicity indicating that o-quinone was involved in cytotoxicity. Dithiothreitol (DTT) greatly reduced 3-HA and 4-MC induced toxicity. The ferric chelator deferoxamine slightly decreased 3-HA and 4-MC induced cytotoxicity whereas the antioxidants pyrogallol or TEMPOL greatly prevented the toxicity suggesting that oxidative stress contributed to 3-HA induced cytotoxicity. In summary, ring hydroxylation but not O-demethylation/epoxidation seems to be the bioactivation pathway for 3-HA in rat liver. The cytotoxic mechanism for 3-HA and its metabolite 4-MC likely consists cellular protein alkylation and oxidative stress. These results suggest that 3-HA is not suitable for treatment of melanoma.     

Role of cytochrome P-450IIE1 in N-nitroso-N-methylaniline induced hepatocyte cytotoxicity.

1. The cytotoxicity of N-nitrosomethylaniline (NMA) towards hepatocytes isolated from rats was prevented by acetone or ethanol (inhibitors for cytochrome P-450IIE1) but not by metyrapone or SKF525A (inhibitors for cytochrome P-450IIB1/2). Various alcohols, secondary ketones and isothiocyanates that induced cytochrome P-450IIE1 were also found to be protective. Various aromatic and chlorinated hydrocarbon solvents that are substrates or inducers of cytochrome P-450IIE1 also prevented NMA cytotoxicity. Nitrogen-containing heterocycles that induced cytochrome P-450IIE1 were less effective. Further evidence that cytochrome P-450IIE1 was responsible for the activation of NMA was the marked increase in hepatocyte susceptibility if hepatocytes from pyrazole-induced rats were used. 2. NMA was more cytotoxic to hepatocytes isolated from phenobarbital-pretreated rats than uninduced rats. However, metyrapone now prevented and SKF525A delayed the cytotoxicity whereas ethanol, acetone, allyl isocyanate, isoniazid or trichloroethylene had no effect on the susceptibility of phenobarbital-induced hepatocytes. Furthermore, microsomes isolated from phenobarbital-pretreated rats had higher NMA-N-demethylase activity which was more inhibited by metyrapone and SKF525A than that of uninduced microsomal activity. By contrast the N-demethylase activity of phenobarbital induced microsomes was more resistant to acetone, ethanol, hexanal, trichloroethylene and toluene than uninduced microsome. 3. The above results suggest that cytochrome P-450IIE1 catalyses the cytotoxic activation of NMA in normal or pyrazole-induced hepatocytes whereas cytochrome P-450IIB1/2 is responsible for cytotoxicity in phenobarbital-induced hepatocytes.     

Differential toxicity of cocaine and its isomers, (+)-cocaine and (-)-psi-cocaine, is associated with stereoselective hydrolysis by hepatic carboxylesterases in cultured rat hepatocytes.

Cocaine induces acute lethal cell injury in rat hepatocytes following N-oxidative metabolic activation by cytochrome P450-dependent and flavin-dependent monooxygenases. Beside this oxidative bioactivation pathway, hepatic carboxylesterases may cleave the carboxymethylester or the benzoylester linkage which leads to molecules found to be non-toxic in vivo. To elucidate the structural requirements of the cocaine molecule for its bioactivation and inactivation, the cytotoxic potential of the natural (-)-cocaine relative to two isomeric forms, (+)-cocaine* (the unnatural enantiomer) and (-)-psi-cocaine (the C2 epimer of the unnatural cocaine) were investigated. Primary short-term cultures of rat hepatocytes obtained from phenobarbital (PB)-pretreated rats were exposed to the drugs for up to 24 h. (-)-Cocaine produced marked time- and concentration-dependent release of lactate dehydrogenase (LDH) into the extracellular medium, whereas the other forms were not cytotoxic (0-1 mM). Furthermore, depletion of cellular glutathione (GSH) with diethylmaleate enhanced LDH release in (-)-cocaine-treated cells and caused marginal cytotoxicity in hepatocytes exposed to the other isomers. To investigate the mechanisms that could be responsible for these isomer-specific effects, the time-dependent metabolic degradation was determined both in cultured hepatocytes and in hepatic microsomes in the presence or absence of the serine carboxylesterase inhibitors, phenylmethylsulfonylfluoride (PMSF) or NaF. All three cocaine analogs were enzymatically degraded, but the rates of ester cleavage greatly varied among the stereoisomers. (-)-Cocaine was primarily N-oxidized via SKF-525A-sensitive pathways, whereas (+)-cocaine was predominantly hydrolyzed by PMSF-sensitive carboxylesterases. In contrast, (-)-psi-cocaine, which is very stable in the absence of cells at 37 degrees C and pH 7.4, was subject to extremely fast enzymatic ester cleavage. In conclusion, these results indicate that the isomer-specific differential cytotoxicity of (-)-cocaine, (+)-cocaine and (-)-psi-cocaine in hepatocytes may be related to stereoselective differences in the rates of hydrolytic inactivation by hepatic carboxylesterases and that the N-oxidative pathway, resulting in hepatocyte injury, may thus be relevant only for (-)-cocaine.     

Cytotoxic activity and fragmentation of aziridines in microsomes

The fragmentation reaction of 2-para-substituted phenyl-N-methylaziridines in rat liver microsomes was studied. The relative reactivity against the substituent group, estimated from the amount of styrenes produced in liver microsomal solution, was para-Cl > para-Me > H > para-NO₂ > para-OMe.The cytotoxic activity of these aziridines was also studied using HeLa cells and L-1210 mouse leukemia cells in free-floating culture. The order of cytotoxic activity with HeLa and L-1210 cells was Cl  Me > H > NO₂  OMe and Me > Cl  OMe > H > NO₂, respectively. The results indicated that the orders of cytotoxic activity and fragmentation reactivity for the parasubstituted aziridines have some parallel relationship. The nitrosomethane generated by fragmentation reaction of aziridine probably plays an important part in the biological activity of aziridines.     

Determination of the intracellular protein thiol distribution of hepatocytes using monobromobimane derivatisation of intact cells and isolated subcellular fractions

The derivatisation of intact rat hepatocytes with monobromobimane resulted in rapid labelling of accessible protein thiols in several subcellular fractions. The derivatisation procedure did not cause acute cytotoxicity, nor did it alter the buoyant densities of the fractions or their gross protein compositions. Quantitation of the fluorescence irreversibly associated with the fractions demonstrated considerable intracellular heterogeneity in this pool of thiols. Values were highest in cytosol (ca. 90 nmol/mg protein), intermediate in microsomes (ca. 65 nmol/mg protein) and mitochondria (ca. 45 nmol/mg protein) and lowest in a crude fraction containing both nuclei and plasma membrane (ca. 35 nmol/mg protein). Similar values were obtained from microsomes and cytosol derivatised after fractionation but there were significant increases of ca. 100% in corresponding values from isolated mitochondria and the nuclear/plasma membrane fraction. These results are discussed in terms of the dynamic fluxes in monobromobimane protein thiols during fractionation and the applicability of this noninvasive method to studies of the mechanism(s) of toxicity of reactive xenobiotics and the role(s) of protein thiols in normal cellular function.     

Endogenous and endobiotic induced reactive oxygen species formation by isolated hepatocytes.

The rat hepatocyte catalyzed oxidation of 2',7'-dichlorofluorescin to form the fluorescent 2,7'-dichlorofluorescein was used to measure endogenous and xenobiotic-induced reactive oxygen species (ROS) formation by intact isolated rat hepatocytes. Various oxidase substrates and inhibitors were then used to identify the intracellular oxidases responsible. Endogenous ROS formation was markedly increased in catalase-inhibited or GSH-depleted hepatocytes, and was inhibited by ROS scavengers or desferoxamine. Endogenous ROS formation was also inhibited by cytochrome P450 inhibitors, but was not affected by oxypurinol, a xanthine oxidase inhibitor, or phenelzine, a monoamine oxidase inhibitor. Mitochondrial respiratory chain inhibitors or hypoxia, on the other hand, markedly increased ROS formation before cytotoxicity ensued. Furthermore, uncouplers of oxidative phosphorylation inhibited endogenous ROS formation. This suggests endogenous ROS formation can largely be attributed to oxygen reduction by reduced mitochondrial electron transport components and reduced cytochrome P450 isozymes. Addition of monoamine oxidase substrates increased antimycin A-resistant respiration and ROS formation before cytotoxicity ensued. Addition of peroxisomal substrates also increased antimycin A-resistant respiration but they were less effective at inducing ROS formation and were not cytotoxic. However, peroxisomal substrates readily induced ROS formation and were cytotoxic towards catalase-inhibited hepatocytes, which suggests that peroxisomal catalase removes endogenous H(2)O(2) formed in the peroxisomes. Hepatocyte catalyzed dichlorofluorescin oxidation induced by oxidase substrates, e.g., benzylamine, was correlated with the cytotoxicity induced in catalase-inhibited hepatocytes.     

An antagonistic effect between aziridine and diaziridine on their cytotoxic activities against L-1210 mouse leukemia cells

The effect of the combination of 1-methyl-2-$\text{p}$-chlorophenylaziridine and 1,2-dimethyl-3-$\text{p}$-chlorophenyldiaziridine on cytotoxic activities against L-1210 mouse leukemia cells was studied. Both compounds clearly showed an antagonistic interaction. The results supported our hypothesis that nitrosomethane formed by the fragmentation of aziridine via the N-oxide in a cellular system causes the cytotoxic behavior of the N-methyl aziridines.     

Modulation of benzoquinone-induced cytotoxicity by diethyldithiocarbamate in isolated hepatocytes

The copper-chelating thiol drug diethyldithiocarbamate protected isolated hepatocytes from benzoquinone-induced alkylation cytotoxicity by reacting with benzoquinone and forming a conjugate which was identified by fast atom bombardment mass spectrometry as 2-(diethyldithiocarbamate-S-yl) hydroquinone. In contrast to benzoquinone, the conjugate was not cytotoxic to isolated hepatocytes. The thiol reductant dithiothreitol had no effect on benzoquinone-induced alkylation cytotoxicity. However, inactivation of catalase in the hepatocytes with azide and addition of the reducing agent ascorbate markedly enhanced the cytotoxicity of the conjugate but did not affect benzoquinone-induced cytotoxicity. Furthermore, inactivation of glutathione reductase and catalase in hepatocytes greatly enhanced the cytotoxicity of the conjugate and caused oxidation of GSH to GSSG. The conjugate also stimulated cyanide-resistant respiration, which suggests that the conjugate undergoes futile redox cycling resulting in the formation of hydrogen peroxide which causes cytotoxicity in isolated hepatocytes only if the peroxide detoxifying enzymes are inactivated. Diethyldithiocarbamate does, however, protect uncompromised isolated hepatocytes from benzoquinone cytotoxicity by conjugating benzoquinone, thereby preventing the electrophile from alkylating essential macromolecules. Diethyldithiocarbamate therefore changed the initiating cytotoxic mechanism of benzoquinone from alkylation to oxidative stress, which was less toxic.     

Cocaine-induced biochemical changes and cytotoxicity in hepatocytes isolated from both mice and rats

The mechanism of cocaine-induced cytotoxicity was investigated in hepatocytes isolated from both male C3H mice and male Sprague-Dawley rats. Cocaine was more cytotoxic to mouse hepatocytes than rat and induced reduced glutathione (GSH) depletion prior to marked increases in cytotoxicity in both systems. In both mouse and rat cells, GSH depletion was accompanied by GSSG production, but in rat cells, quantitative measures suggested that other mechanisms contributed to GSH depletion. No cocaine-induced depletion of protein-thiol groups or generation of protein-glutathione mixed disulfides could be detected in rat cells. Cocaine induced lipid peroxidation, using malondialdehyde (MDA) production as an index of the peroxidation process, in both mouse and rat hepatocytes. Inhibition of MDA production to below control levels using the antioxidant N,N'-diphenyl-phenylene diamine (DPPD) however, had no inhibitory effect on cocaine-induced cytotoxicity in either mouse or rat cells. These data suggest that neither generalized protein thiol depletion nor lipid peroxidation are critical determinants of cocaine-induced cytotoxicity in cellular systems.     

Application of quantitative structure-toxicity relationships for acute NSAID cytotoxicity in rat hepatocytes

Non-steroidal anti-inflammatory agents (NSAIDs) are widely used for pain relief. However, they have been associated with harmful and sometimes fatal side effects. Usually, the target organs are the GI tract and liver. In this study, we have investigated the physicochemical requirements of 21 NSAIDs for glucuronidation and cytotoxicity by quantitative structure-toxicity relationships (QSTRs) in isolated rat hepatocytes. Furthermore, we have investigated the contrast in physicochemical variables that correlated with NSAID-induced hepatocyte cytotoxicity when glucuronidation was inhibited with borneol. The competitive inhibition of hepatocyte p-nitrophenol glucuronidation by NSAIDs was determined by HPLC. Glucuronidation-inhibited hepatocytes were more susceptible to NSAID-induced cytotoxicity. Also, we found a parabolic correlation between lipophilicity and the inhibition of glucuronidation for a subset of NSAIDs. For NSAIDs with a benzoic acid moiety, cytotoxicity also correlated parabolically with lipophilicity, but correlated linearly with the HOMO-LUMO gap, and the first-order valence connectivity index. The cytotoxicity of NSAIDs with a phenylacetic acid (or propionic acid) substructure also correlated with lipophilicity, but not with the HOMO-LUMO gap. Our findings indicated that the inhibition of glucuronidation resulted in increased NSAID cytotoxicity, suggesting that acyl-glucuronide metabolites were acutely less cytotoxic. Also, comparative QSTRs revealed that benzoic acid NSAIDs may form cytotoxic radical metabolites (parameterized by the HOMO-LUMO gap) or alter mitochondrial respiration (parameterized by the connectivity index), whereas phenylacetic acid derived NSAIDs may form different cytotoxic metabolites, since they did not correlate with these parameters. In summary, we have used QSTRs as a tool to distinguish the cytotoxic mechanism of two groups of NSAIDs, which, if analyzed together as one group, did not reveal such mechanism-based differences.     

Lethal injury by diquat redox cycling in an isolated hepatocyte model

Hepatocyte isolated by collagenase perfusion of livers of male Fischer-344 rats, and treated with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) (50 microM for 30 min at 37 degrees C) to inhibit glutathione reductase, were significantly more vulnerable to cytotoxicity of the bipyridyl herbicide diquat than similarly treated cells of Sprague-Dawley rats. Without compromise of cell defenses by BCNU, diquat was not cytotoxic to hepatocytes from either strain. Microsomal enzyme induction with phenobarbital (80 mg/kg ip for 3 days before hepatocyte isolation) did not potentiate killing of Fischer hepatocytes by diquat. Specific activities of NADPH-cytochrome P-450 reductase in isolated Fischer and Sprague-Dawley rat liver microsomes utilizing 1 mM diquat as acceptor were 0.085 +/- 0.017 and 0.076 +/- 0.028 mumol/mg.min (mean +/- SEM, N = 5), respectively, indicating the capacity for very active redox cycling of diquat by this route in both strains. The serine protease inhibitor, phenylmethylsulfonyl fluoride (100 microM), had no effect on diquat cytotoxicity, but both leupeptin (100 micrograms/ml) and antipain (50 or 100 microM) were able to delay, through not completely prevent, diquat-induced cell death. The phospholipase inhibitors, chlorpromazine (50 or 100 microM) and dibucaine (50 or 100 microM), similarly delayed but did not prevent cell death. Diquat increased the rate of hepatocyte phospholipid hydrolysis, measured as release into the suspending medium of [14C]arachidonic acid previously incorporated into hepatocyte lipids, but although chlorpromazine decreased phospholipid hydrolysis to the control rate, only partial protection against diquat cytotoxicity was seen. These data suggest that activation of phospholipase A2 and proteases by elevation of cytosolic free Ca2+ cannot account entirely for the loss of cell viability observed in the presence of cytotoxic concentrations of diquat.     

Oxygen dependence and subcellular partitioning of hepatic menadione-mediated oxygen uptake. Studies with isolated hepatocytes, mitochondria, and microsomes from rat liver in an oxystat system

Using an oxystat system, menadione (2-methyl-1,4-naphthoquinone)-mediated oxygen uptake was investigated in isolated rat hepatocytes, in malate/glutamate-supplemented mitochondria, and in NADPH-reduced microsomes at steady-state oxygen partial pressures (pO2) between 0.1 to 100 mm Hg (0.2-150 microM O2). Menadione-mediated stimulation of oxygen uptake was half-maximal at pO2 of 0.5, 0.2, and 0.9 mm Hg, respectively. In hepatocytes and mitochondria half-maximal concentrations of menadione were 15 and 4 microM. However, in microsomes saturation with menadione was not reached at concentrations up to 300 microM. Antimycin A inhibited menadione-mediated oxygen uptake in hepatocytes and mitochondria by about three-fourths, while rotenone was without inhibitory effect; KCN inhibited practically completely. In mitochondria menadione-stimulated oxygen uptake was significantly inhibited by dicoumarol but further enhanced by the addition of ADP, even in the presence of rotenone. The results suggest that menadione-mediated hepatocellular oxygen uptake proceeds almost independently of pO2 in most regions of the liver lobule but that in areas of low pO2 such as the centrolobular regions limitation by oxygen may occur. They also demonstrate that in the intact hepatocyte menadione-mediated oxygen uptake predominantly (greater than 90%) results from electron transfer in the mitochondrial respiratory chain by menadione.     

Tumor necrosis factor production by human monocytes is a regulated event: induction of TNF-alpha-mediated cellular cytotoxicity by endotoxin

Expression of cellular cytotoxicity by monocytes or macrophages has been conceived as an induced function secondary to collaboration in the immune response or to other agonists. However, a form of spontaneous cellular cytotoxicity by monocytes analyzed with unseparated human peripheral blood mononuclear cells (PBM) has been described by using the 6-hr 51Cr release from actinomycin D (ActD)-treated murine WEHI 164 cells, a target cell refractory to the cytotoxic effects of natural killer and cytolytic T cells. We observe that when cells are isolated under rigorously endotoxin-free conditions, there is no cytotoxicity. Inclusion of serum does not induce cellular cytotoxicity; however, cytotoxic activity is induced by the presence of as little as 1 pg/ml of bacterial lipopolysaccharide (LPS). PBM required 2 hr of preexposure to endotoxin in order to express full cytotoxic activity. We investigated the basis of the cytotoxicity of WEHI 164 cells and the effect of ActD. ActD-treated target cells are highly susceptible to the effects of TNF-alpha and TNF-beta (alpha-lymphotoxin), whereas untreated target cells were resistant. In contrast, ActD does not affect susceptibility to the cytotoxic effects of H2O2, and interleukin 1 is not cytotoxic to the target cells. With the use of a neutralizing monoclonal antibody specific for TNF-alpha, the cytotoxic activity induced by LPS greatly diminished and the amount of TNF-alpha neutralized is similar to that required for equivalent cytotoxicity. We conclude that monocytes present in human PBM are not "spontaneously" cytotoxic for ActD-treated WEHI 164 target cells, but that the reported cytotoxicity results from exposure to a level of endotoxin or endotoxin-like agonists to which the cells are exposed. The cytotoxicity is mediated mostly if not entirely by TNF-alpha, an established product of monocytes/macrophages. With the use of endotoxin-free conditions, PBM can be isolated in a cytotoxically latent state, suitable for analysis of the immunologic regulation of TNF-alpha-mediated monocyte cellular cytotoxicity.     

Identification and analysis of the active phytochemicals from the anti-cancer botanical extract Bezielle

Bezielle is a botanical extract that has selective anti-tumor activity, and has shown a promising efficacy in the early phases of clinical testing. Bezielle inhibits mitochondrial respiration and induces reactive oxygen species (ROS) in mitochondria of tumor cells but not in non-transformed cells. The generation of high ROS in tumor cells leads to heavy DNA damage and hyper-activation of PARP, followed by the inhibition of glycolysis. Bezielle therefore belongs to a group of drugs that target tumor cell mitochondria, but its cytotoxicity involves inhibition of both cellular energy producing pathways. We found that the cytotoxic activity of the Bezielle extract in vitro co-purified with a defined fraction containing multiple flavonoids. We have isolated several of these Bezielle flavonoids, and examined their possible roles in the selective anti-tumor cytotoxicity of Bezielle. Our results support the hypothesis that a major Scutellaria flavonoid, scutellarein, possesses many if not all of the biologically relevant properties of the total extract. Like Bezielle, scutellarein induced increasing levels of ROS of mitochondrial origin, progressive DNA damage, protein oxidation, depletion of reduced glutathione and ATP, and suppression of both OXPHOS and glycolysis. Like Bezielle, scutellarein was selectively cytotoxic towards cancer cells. Carthamidin, a flavonone found in Bezielle, also induced DNA damage and oxidative cell death. Two well known plant flavonoids, apigenin and luteolin, had limited and not selective cytotoxicity that did not depend on their pro-oxidant activities. We also provide evidence that the cytotoxicity of scutellarein was increased when other Bezielle flavonoids, not necessarily highly cytotoxic or selective on their own, were present. This indicates that the activity of total Bezielle extract might depend on a combination of several different compounds present within it.     

Inhibition by secalonic acid D of oxidative phosphorylation and Ca2+-induced swelling in mitochondria isolated from rat livers

The in vitro biological activity of secalonic acid D, a mycotoxin from Aspergillus ochraceus, was studied to assess its cytotoxicity for isolated rat liver mitochondria. Secalonic acid D uncoupled the oxidative phosphorylation of mitochondria and caused a mild inhibition of state 3 respiration. Secalonic acid D weakly enhanced latent ATPase activity in mitochondria but suppressed 2,4-dinitrophenol-stimulated ATPase activity. Secalonic acid D did not induce pseudoenergized swelling of mitochondria and markedly inhibited the Ca2+-induced swelling of mitochondria in KCl isotonic solution.     

Inhibition by secalonic acid D of oxidative phosphorylation and Ca2+-induced swelling in mitochondria isolated from rat livers.

The in vitro biological activity of secalonic acid D, a mycotoxin from Aspergillus ochraceus, was studied to assess its cytotoxicity for isolated rat liver mitochondria. Secalonic acid D uncoupled the oxidative phosphorylation of mitochondria and caused a mild inhibition of state 3 respiration. Secalonic acid D weakly enhanced latent ATPase activity in mitochondria but suppressed 2,4-dinitrophenol-stimulated ATPase activity. Secalonic acid D did not induce pseudoenergized swelling of mitochondria and markedly inhibited the Ca2+-induced swelling of mitochondria in KCl isotonic solution.     

Inhibition of fumarase by S-2,3-dicarboxyaziridine

S-2,3-Dicarboxyaziridine was found to be a potent competitive inhibitor (Ki = 0.08 microM) of fumarase from pig heart. The aziridine did not inactivate the enzyme or exhibit any observable substrate activity. It is likely that it functions as a transition state analogue mimicking the carbanion intermediate found in the normal catalytic reaction. The aziridine inhibited fumarate utilization in ruptured but not intact mitochondria.     

The role of heme and the mitochondrion in the chemical and molecular mechanisms of mammalian cell death induced by the artemisinin antimalarials

The artemisinin compounds are the frontline drugs for the treatment of drug-resistant malaria. They are selectively cytotoxic to mammalian cancer cell lines and have been implicated as neurotoxic and embryotoxic in animal studies. The endoperoxide functional group is both the pharmacophore and toxicophore, but the proposed chemical mechanisms and targets of cytotoxicity remain unclear. In this study we have used cell models and quantitative drug metabolite analysis to define the role of the mitochondrion and cellular heme in the chemical and molecular mechanisms of cell death induced by artemisinin compounds. HeLa ρ(0) cells, which are devoid of a functioning electron transport chain, were used to demonstrate that actively respiring mitochondria play an essential role in endoperoxide-induced cytotoxicity (artesunate IC(50) values, 48 h: HeLa cells, 6 ± 3 μM; and HeLa ρ(0) cells, 34 ± 5 μM) via the generation of reactive oxygen species and the induction of mitochondrial dysfunction and apoptosis but do not have any role in the reductive activation of the endoperoxide to cytotoxic carbon-centered radicals. However, using chemical modulators of heme synthesis (succinylacetone and protoporphyrin IX) and cellular iron content (holotransferrin), we have demonstrated definitively that free or protein-bound heme is responsible for intracellular activation of the endoperoxide group and that this is the chemical basis of cytotoxicity (IC(50) value and biomarker of bioactivation levels, respectively: 10β-(p-fluorophenoxy)dihydroartemisinin alone, 0.36 ± 0.20 μM and 11 ± 5%; and with succinylacetone, >100 μM and 2 ± 5%).     

Potentiation of dimethylnitrosamine genotoxicity in rat hepatocytes isolated following ethanol treatment in vivo

Unscheduled DNA synthesis (UDS), following exposure to dimethylnitrosamine (DMN), was potentiated in cultured hepatocytes isolated following treatment of rats for 14 or 28 days with 20% ethanol/5% sucrose solution. Ethanol treatment was associated with increased UDS, a concomitant increase in hepatic microsomal protein concentration and DMN N-demethylase activity. Increased aniline hydroxylase activity of hepatic microsomes from ethanol-treated rats preceded the measured increase in microsomal protein content or DMN metabolism. The increase in metabolism of DMN in vitro and potentiation of DMN-induced UDS associated with ethanol treatment may contribute to a synergistic effect of ethanol on DMN hepatotoxicity and carcinogenicity. In contrast, ethanol pretreatment did not increase the cytotoxicity of DMN as characterized by enzyme release.     

Comparative genotoxicity studies of the flame retardant tris(2,3-dibromopropyl)phosphate and possible metabolites

Tris(2,3-dibromopropyl)phosphate (Tris-BP) was activated to mutagens in the Salmonella/microsome quantitative test system. Liver microsomes from rats pretreated with phenobarbital (PB) increased the mutagenicity of 0.05 mM Tris-BP to 186% of the activity obtained with liver microsomes from untreated rats. The addition of 0.02 mM Tris-BP to V79 Chinese hamster cells co-incubated with liver microsomes from PB-pretreated rats increased the number of mutants by a factor of 9.7. Tris-BP also caused genotoxic and cytotoxic responses in primary monolayers of rat hepatocytes. The relative increase in unscheduled DNA synthesis after treatment with 0.05 mM Tris-BP was 2.3-fold as measured by scintillation counting of radiolabelled thymidine incorporated into DNA of isolated nuclei. The use of hepatocytes isolated from PB-pretreated rats reduced the increases in DNA repair synthesis relatively to that in control cells. Monolayers of hepatocytes from untreated rats co-cultured with Salmonella typhimurium TA100 activated Tris-BP to mutagenic intermediates which were released into the culture medium. The studies with the V79 and liver-cell systems indicate that the reactive intermediates formed from Tris-BP are sufficiently stable and lipophilic to traverse the various membranes from the site of generation to the respective cellular targets. The relative degree of genotoxic responses of bis(2,3-dibromopropyl)phosphate, 2,3-dibromopropylphosphate, tris(2,3-bromopropyl)phosphate, tris(2-bromopropyl)phosphate and 2,3-dibromopropanol in the systems studied did not indicate that these compounds were proximate or ultimate reactive metabolites of Tris-BP in liver-derived activation systems.