INTRODUCTION

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Within cells, oxidative stress can lead to potential harm by causing nucleic acid damage, protein oxidation, and lipid peroxidation (17). Reactive oxygen species (ROS) that can induce such a stress response include the superoxide anion (O₂), the hydroxyl radical (OH^·), hydrogen peroxide (H₂O₂), and lipid hydroperoxides (17, 25). Incomplete reduction of molecular oxygen to water in the respiratory electron transport chain leads to increased production of ROS during aerobic metabolism. ROS production can also increase following the exposure of cells to certain environmental conditions (17). Oxidative stress is significant both environmentally and medically, as it has been strongly implicated in diseases such as asthma, cancer (17), and atherosclerosis (51), in the aging process (2), and in AIDS (38).

One major target of ROS attack is unsaturated lipids, leading to autocatalytic lipid peroxidation (25). This is a significant source of membrane damage, which may contribute to atherosclerosis (51). During lipid peroxidation, reactive lipid and fatty acid hydroperoxides are formed, and these contribute to ongoing autooxidation (25). Lipid hydroperoxides also play a key role in the development of eye cataracts and hepatic diseases, and they act as substrates for pathways that yield leukotrienes and lipoxins as part of the inflammatory response (2, 51). Fatty acid hydroperoxides have been shown to be more toxic than phospholipid hydroperoxides to endothelial cells (29), and it has been shown that phospholipid hydroperoxides are broken down to the fatty acid hydroperoxide moiety to exert their toxic effects (28). Under certain conditions, linoleic acid hydroperoxide (LoaOOH) can form a delocalized lipid radical (L') which self-reacts to form dienoic dimers (L"L) or reacts with another hydroperoxide to form the peroxy radical (LOO') (16). High levels of lipid hydroperoxides are also found in plants following environmental stress or physical injury (5), and these compounds are important in food rancidity and aging (2, 42).

Enzymes involved in the breakdown of lipid hydroperoxides may include phospholipases, glutathione peroxidase and phospholipid hydroperoxide glutathione peroxidase, which is specific to phospholipid hydroperoxides (35), thioredoxin reductase (6), and cytochrome P-450 enzymes (46). The lipoxygenase enzyme, which is used to generate lipid hydroperoxides in vitro, can also use them as a substrate (16).

The model eukaryote Saccharomyces cerevisiae is ideal for investigating oxidative-stress responses, since not only is it genetically well defined but its defense systems against ROS are well characterized, including enzymes such as superoxide dismutase and catalase, as well as nonenzymic antioxidants (34). One major nonenzymic antioxidant in yeast is glutathione (20), which is a low-molecular-weight thiol present at millimolar levels in the cell (36) and which may be important in detoxifying cellular lipid hydroperoxides. Glutathione is the substrate for enzymes such as glutathione peroxidase, which has been shown to be important for the response to lipid hydroperoxides in Hansenula mrakii (27). In addition, some toxic compounds are conjugated to glutathione by glutathione S-transferase for transport out of the cell (26).

In this study, the effects of LoaOOH will be examined by using a wild-type yeast and isogenic mutants affected in known antioxidant defense systems. Additionally, the role of respiration-related processes in both defense and adaptation to fatty acid hydroperoxides will be investigated by treating isogenic respiration-incompetent petite mutants with LoaOOH, and results will be compared to those seen with other oxidants. The possible role of glutathione in the cellular response to LoaOOH will also be determined.

	MATERIALS AND METHODS

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Yeast strains and growth conditions. Studies were performed with the wild-type yeast strain CY4 (DY150 Amrad) (MATa ura3-52 leu2-3 leu2-112 trp1-1 ade2-1 his3-11 can1-100), which was the parent strain for the isogenic derivatives CY7 (glr1::TRP1), CY9 (gsh1::LEU2), CY29 (yap1::HIS3), CY102 (cox6::HIS3), CY103 (coq3::HIS3) (23), CY97 (gsh2::HIS3), and the [rho⁰] petite mutant CY4p (19, 21, 23, 24), and also with the wild-type yeast strain W303-1B, which was the parent strain of its isogenic coq3 and atp2 mutants (10) and its [rho⁰] petite mutant (generated by using ethidium bromide). All mutants were obtained by standard gene disruption techniques. Cells were grown in YEPD medium (1% [wt/vol] yeast extract, 2% [wt/vol] Bacto Peptone, 2% [wt/vol] D-glucose) at 30°C with shaking unless otherwise stated. Growth on nonfermentable carbon sources was tested on YEPG medium (YEPD medium with glucose replaced by 3% [vol/vol] glycerol).

Synthesis of LoaOOH. LoaOOH was generated in vitro similarly to a method previously described (41), by incubating linoleic acid (0.3 mM) with soybean lipoxygenase (4,000 U) in 0.1 M tetra-sodium borate buffer (pH 9) at room temperature with vigorous stirring for 30 min. The enzyme catalyzes abstraction of the H-11 hydrogen, which leads to the specific formation of Loa-13-OOH (45). The reaction mixture was loaded onto an end-capped C₁₈ reverse-phase column (Sepak cartridge), and the LoaOOH was eluted in 1.5 ml of methanol. The solution was stored at 20°C and was stable for several months. The concentration of LoaOOH was determined spectrophometrically ( = 234 nm;  = 25,000 M¹ cm¹). High-pressure liquid chromatographic analysis (C₁₈ column RPMET4.A; 2 ml min¹ flow rate; 85% [vol/vol] acetonitrile; 15% [vol/vol] 0.2% acetic acid; 234 nm) was used to show that the resultant product was at least 95% pure and contained only trace amounts of linoleic acid (data not shown).

LoaOOH treatment and adaptation experiments. Cells were grown to exponential phase (2 × 10⁷ cells ml¹) in YEPD medium, and to 3-ml aliquots of the culture was added LoaOOH to a range of concentrations (0 to 0.5 mM) for 1 h. Samples from each treatment were diluted in fresh YEPD medium and plated in triplicate on YEPD in order to obtain viable counts and generate the respective dose-response curves. Adaptation was measured by pretreating cells with a nonlethal dose of LoaOOH (0.05 mM) for 1 h, followed by treatment with a lethal dose (0.2 mM) for 1 h. Untreated (receiving no pretreatment or treatment), non-pretreated (receiving the treatment dose only), and pretreated (receiving the pretreatment dose only) controls were run simultaneously. Control reactions in which either the substrate linoleic acid or the enzyme lipoxygenase was excluded from the reaction were also performed. These controls were used to treat aliquots of the same culture in order to ensure that the effect seen was a result of LoaOOH. An additional control reaction with methanol alone, equivalent to the highest concentration of LoaOOH used, was also performed on the same culture. Data are means of triplicates from a representative experiment.

Calculation of yeast cell volume. The cells were observed with phase-contrast optics at ×400 total magnification. Volumes (V) were calculated from the major (a) and minor (b) diameters of >50 cells by assuming that they were prolate spheroids where V = ab²/6. This is reportedly accurate to ±10% (49).

Detection of petite mutants. Yeast colonies were tested for their ability to respire by using a 10-ml overlay of 1% (wt/vol) triphenyltetrazolium chloride (TTC) in 12% (wt/vol) water agar. The solution was boiled, and after cooling it was overlaid onto YEPD plates with fresh colonies and incubated at 30°C for 1 h. Cells that formed pink colonies were able to respire and thus reduce TTC to a red dye via the electron transport chain, while petite mutants, which are unable to respire, remained white (7). The petite nature of cells in a colony was also detected by failure to grow on the nonfermentable carbon source glycerol (YEPG).

MDA treatment. Cells were grown to exponential phase (2 × 10⁷ cells ml¹) in YEPD medium and were harvested by centrifugation. The pellet was resuspended in 0.1 M sodium citrate buffer, pH 4.5, and cells were either pretreated with 1 mM malondialdehyde (MDA) or treated with 5 mM MDA for 1 h at 30°C (as was appropriate to the experiment) and allowed to recover in fresh YEPD medium for 1 h (47). Samples from each treatment were diluted in fresh YEPD medium and plated in triplicate on YEPD in order to obtain viable counts and generate the respective dose-response curves.

Treatment with superoxide-generating agents and other peroxides. For cross-adaptation experiments using H₂O₂, tert-butyl hydroperoxide, cumene hydroperoxide, paraquat, and menadione, the pretreatment concentrations were 0.3, 1, 1, 10, and 0.2 mM, respectively. Following pretreatment with 0.05 mM LoaOOH for 1 h, treatment concentrations for these reagents were 5, 12, 4, 15, and 6 mM, respectively. All treatments were carried out for 1 h at 30°C with shaking.

Treatment with argon and oxygen. Prior to the addition of different concentrations of LoaOOH, either pure argon or pure oxygen was bubbled through the culture aliquots for 15 min; this was continued during the 1-h treatment with LoaOOH. Samples were then diluted and plated for viability counts as previously described.

Glutathione and glutathione peroxidase assays. Glutathione levels were determined by a microtiter plate assay described previously (48). Total, Se-dependent, and Se-independent glutathione peroxidase activity was determined by using the previously described coupled assay (31) in which oxidized glutathione, produced by the hydroperoxide-dependent oxidation of reduced glutathione, is reduced by glutathione reductase. NADPH is consumed during this reaction, and a decrease in absorbance is measured. Crude cell extract from cultures grown to exponential phase (optical density at 600 nm [OD₆₀₀] = 1) was used. Specific activity is defined as nanomoles of NADPH oxidized per minute per milligram of protein.

	RESULTS AND DISCUSSION

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Yeast membranes do not normally contain polyunsaturated fatty acids; instead, 30 to 50% of the phospholipid bilayer consists of palmitoleic acid (9-hexadecenoic acid), which is monounsaturated (25). However, polyunsaturated fatty acids (such as linoleic acid) in the medium are incorporated into the yeast membrane (8). Lipid peroxidation can be initiated with any unsaturated fatty acid, including the monounsaturated fatty acids oleic and palmitoleic acids, resulting in products that are similar to those which occur in the presence of polyunsaturated fatty acids (25). For these reasons, it was desirable to determine the effect of a lipid peroxidation intermediate, such as LoaOOH, on S. cerevisiae, since yeast are exposed to lipid hydroperoxides in their natural environment.

LoaOOH is toxic to yeast. The possible toxicity of LoaOOH to the wild-type yeast strain CY4 was determined by treating cells with different doses of LoaOOH. Different concentrations of LoaOOH were added to cultures in the same growth medium (YEPD), and incubation continued with vigorous aeration at 30°C for 1 h. Concentrations greater than 0.05 mM caused a decrease in cell viability such that after 0.2 mM treatment there was less than 10% survival (Fig. 1A). Appropriate controls were run simultaneously with these experiments, and no effect was observed (Fig. 1A). These included treatment of cells with linoleic acid, which was not toxic at a concentration equivalent to the lethal dose of LoaOOH. LoaOOH is toxic at concentrations much lower than those for hydrogen peroxide or other organic peroxides. To obtain <10% survival with this strain under the same conditions, higher concentrations of H₂O₂ (6 mM) (21), tert-butyl hydroperoxide (15 mM), and cumene hydroperoxide (4 mM) (results of this study) are required.

View larger version (15K): [in this window] [in a new window]   FIG. 1.   Sensitivity of yeast cells to LoaOOH. (A) Wild-type cells grown to an OD600 of 1 in YEPD medium were treated with LoaOOH for 1 h at 30°C. Cells were diluted and plated in triplicate onto YEPD medium to monitor cell viability. Percent survival is expressed relative to the untreated control culture (100%). Symbols: , LoaOOH-treated cells; , methanol-treated control; , linoleic acid control; , lipoxygenase control. (B) The kinetics of cell death was determined by sampling untreated and treated cultures at 20-min intervals for 1 h, using different concentrations of LoaOOH as indicated. Data are means of triplicates from a representative experiment.

Yeast can adapt to LoaOOH. Given that lipid hydroperoxides may be formed in aerobic cells with unsaturated fatty acids in their membrane lipids, the question arises whether cells have a mechanism to respond to the presence of these compounds and detoxify them. Yeast cells are able to adapt to a range of oxidants and free radical-generating agents (11, 15) as well as to the lipid peroxidation product MDA (47). Adaptation is noted when cells display increased tolerance to a lethal dose of a particular compound following pretreatment with a sublethal dose, and this is indicated by a higher percentage of cell survival relative to survival of the non-pretreated control. The number of viable cells in the untreated control after the same time period was considered 100% cell survival. The adaptive response was observed when CY4 cells were pretreated with a sublethal dose of LoaOOH (0.05 mM; 1 h) and found to be more resistant to a subsequent treatment with a lethal dose (0.2 mM; 1 h) than those which received no pretreatment (Fig. 2). This result indicates that there may be an inducible system which allows yeast either to detoxify LoaOOH directly or to mount a cellular defense against this compound. Either mechanism would likely involve alteration in the expression of several genes and/or modification of proteins, and this can be partly determined by using inhibitors of protein synthesis.

View larger version (25K): [in this window] [in a new window]   FIG. 2.   Adaptation of wild-type cells to a lethal dose of LoaOOH. Cells can mount an inducible adaptive response to LoaOOH which is dependent on protein synthesis. Cells were pretreated with a sublethal dose of LoaOOH (0.05 mM; 1 h) prior to challenge with a lethal dose (0.2 mM; 1 h). The cytosolic protein synthesis inhibitor CHX was used at a concentration of 25 µg ml1. Data are means of triplicates from a representative experiment.

De novo protein synthesis is required for adaptation. To determine if ongoing cytoplasmic protein synthesis was required to elicit the adaptive response, cells of the same culture were pretreated with 25 µg of the inhibitor cycloheximide (CHX) ml¹, 0.05 mM LoaOOH, or both of these together (Fig. 2). These cells were subsequently treated with the lethal concentration of LoaOOH, as was the non-pretreated control. Control LoaOOH-pretreated cells displayed the usual adaptive response. Interestingly, CHX pretreatment alone led to protection of the cells (to almost the same degree as LoaOOH); this has been observed for other stress responses and indicates that cells may have some posttranslational change that confers resistance to LoaOOH, or that recovery of cells from LoaOOH treatment can be improved by CHX pretreatment, since it may lead to induction of repair processes once the CHX and LoaOOH are removed. It has been reported that CHX can lead to increased transcription of several genes (32), which, through action during the recovery phase, may account for the adaptive response seen. Given the above results, it is also interesting that those cells pretreated with both CHX and LoaOOH together were found to be more sensitive than the non-pretreated control (Fig. 2), which indicated that de novo protein synthesis in the cytoplasm is necessary for LoaOOH adaptation, while the cells are exposed to LoaOOH.

Presence of oxygen is required for maximal toxicity. Lipid peroxidation is an autocatalytic process which requires the involvement of molecular oxygen. Hence, to examine the effect of oxygen on LoaOOH toxicity, cells were treated with different concentrations of LoaOOH in the presence of pure oxygen or argon (see Materials and Methods). With the wild-type grande strain, resistance to LoaOOH decreased markedly in the presence of oxygen and increased in the presence of argon (Fig. 3); the petite strain behaved similarly to the grande strain under the same conditions (data not shown). These results indicate that oxygen contributes significantly to the increased toxicity of LoaOOH. Lipid hydroperoxides can also break down to produce toxic carbonyl compounds, including MDA, and the question arises whether this product of lipid peroxidation can induce the defense system against LoaOOH.

View larger version (13K): [in this window] [in a new window]   FIG. 3.   The presence of oxygen is required for maximal sensitivity to LoaOOH. Pure oxygen or argon was bubbled through culture aliquots for 15 min prior to addition of different concentrations of LoaOOH for 1 h. Cell viability was determined as described for Fig. 1 and compared to that of a control which received LoaOOH treatment only. Data are means of triplicates from a representative experiment.

Cross-adaptation to MDA and heat shock. Pretreatment of cells with a sublethal dose of MDA (1 mM; 1 h) conferred resistance to a subsequent treatment with 0.2 mM LoaOOH (Fig. 4A). The adaptive response with MDA pretreatment was significantly greater than that seen when cells were pretreated with LoaOOH, which indicates that an efficient system dealing with LoaOOH is triggered upon MDA exposure. However, when the cells were pretreated with 0.05 mM LoaOOH, no increased resistance to MDA was detected (data not shown). This is interesting, and a probable explanation lies with the concentrations that are required to lead to toxic effects. LoaOOH is toxic at concentrations 10-fold lower than those for MDA, and as a weak acid, MDA accumulates within cells at concentrations above those added exogenously (47). This also indicates that there may be at least two defense systems dealing with the products of lipid peroxidation and that these may overlap to some degree. Furthermore, it could be postulated that with time a breakdown product of LoaOOH may induce resistance to MDA and that this was not seen in the time course of this experiment, or that MDA induces various membrane transporters (such as PDR5 [4]), which leads to multidrug resistance and therefore to removal of LoaOOH or its breakdown products.

View larger version (24K): [in this window] [in a new window]   FIG. 4.   Cross-adaptation to other stresses indicates overlapping response systems. (A) Adaptation of wild-type cells to a lethal dose of LoaOOH (0.2 mM; 1 h) following pretreatment with a sublethal dose of MDA (1 mM; 1 h). (B) Adaptation of wild-type cells to a lethal dose of LoaOOH (0.2 mM; 1 h) following pretreatment with a mild heat shock (37°C; 1 h). (C) Fold adaptation, following pretreatment with a sublethal dose of LoaOOH (0.05 mM; 1 h), to the organic hydroperoxides cumene hydroperoxide (COOH; 4 mM) and tert-butyl hydroperoxide (tBOOH; 12 mM), the superoxide-generating agents paraquat (PQ; 15 mM) and menadione (MD; 6 mM), MDA (5 mM), and H2O2 (5 mM). An asterisk indicates that no adaptive response was detected. Data are means of triplicates from a representative experiment.

Pretreatment with LoaOOH confers resistance to H₂O₂ but not to superoxide anions or other organic hydroperoxides. Previous work has shown that there is a complex set of interactions between different forms of oxidative stress in terms of their abilities to induce cross-protection against other compounds, and therefore, distinct detoxification and adaptive responses may exist. Pretreatment with the sublethal dose of LoaOOH (0.05 mM) did not induce further resistance to organic hydroperoxides, but it did confer increased resistance to H₂O₂ (Fig. 4C). It is possible that the activities of enzymes involved in the detoxification of H₂O₂, such as catalase (34), cytochrome c peroxidase (40), and glutathione peroxidase (37) increase following treatment with LoaOOH. Of these enzymes, glutathione peroxidase activity was measured, since it has also been shown to detoxify lipid hydroperoxides under certain conditions (35). Total and Se-dependent glutathione peroxidase activity was detectable in crude cell extracts of S. cerevisiae prepared from untreated cells, and this increased following treatment with doses of LoaOOH in the range of 0.05 to 0.12 mM, where a 0.08 mM dose resulted in approximately 50% cell viability under the conditions used (Table 1). The total activity of glutathione peroxidase increases following treatment with LoaOOH, and this induction of glutathione peroxidase may therefore be the basis of the increased resistance to H₂O₂. Putative glutathione peroxidase genes have been identified within the S. cerevisiae genome, as have glutathione S-transferases, which are also known to have glutathione peroxidase activity (39), and it is the aim of future studies to determine the role of these genes in the LoaOOH response.

Glutathione and the transcriptional activator yAP-1 play important roles in cellular defense against LoaOOH. Glutathione is an abundant intracellular thiol found to be important in the response to other types of oxidative stress (20). To determine if glutathione plays a role in the cellular defense against LoaOOH, the sensitivity of a mutant unable to synthesize glutathione was tested. CY9 lacks GSH1, which encodes -glutamylcysteine synthetase, which is the first and rate-limiting step in glutathione synthesis (36). Surprisingly, CY9 was more resistant to LoaOOH than the wild type (Fig. 5). Since the gsh1 mutant is phenotypically petite in that it lacks mitochondrial function, it is important to compare its resistance to that of the [rho⁰] petite mutant generated from the wild-type parent (21) (Fig. 5). CY9 (gsh1) was more sensitive than CY4p ([rho⁰]), and therefore glutathione may play some role in the cellular defense against LoaOOH. The respiration-competent gsh2 mutant (CY97), which cannot form glutathione but is able to synthesize the dipeptide -glutamylcysteine (22), showed no difference in sensitivity from the wild type when treated with LoaOOH (Fig. 5). This finding indicates that the dipeptide can effectively substitute for glutathione in this response, and this is the first report of such a role in response to lipid hydroperoxides. From these results, it might be expected that cellular glutathione levels alter following LoaOOH treatment; hence, cells were treated as described previously and total free-glutathione levels were assayed, as well as the ratio of oxidized to reduced glutathione, which reflects the redox status of the cell (48).

View larger version (16K): [in this window] [in a new window]   FIG. 5.   Sensitivities of the wild type and oxidative-stress mutants to LoaOOH. Yeast strains CY4 (wild type), CY4p ([rho0] petite mutant), CY9 (gsh1 petite mutant), CY97 (gsh2), CY7 (glr1), and CY29 (yap1) were grown to exponential phase and treated with various concentrations of LoaOOH for 1 h. Samples were diluted and plated on YEPD to monitor cell viability. Data are means of triplicates from a representative experiment.

Respiration-deficient cells are resistant, and inhibition of respiration can increase resistance to LoaOOH. Previously it was found that treatment of a wild-type culture with LoaOOH led to the selection of petite mutants as survivors. This is surprising, since previous studies in yeast have shown that petite strains are generally more sensitive than the wild type to different types of stress, including oxidant exposure (11, 15, 23, 47). The finding that petite mutants were more resistant to LoaOOH raises the question of what role the mitochondrion plays in the toxicity of LoaOOH, especially since mutations in the mitochondrial genome can enhance oxidative stress (40). It is unlikely that mitochondrial DNA is a target for LoaOOH, since the frequency of petite-mutant generation did not increase during the treatments used. To investigate the role of mitochondrial function, the sensitivity of an isogenic [rho⁰] petite mutant (CY4p) was compared to that of the wild-type grande strain. Petite mutants do not lack all mitochondrial functions, since nuclear-encoded proteins can continue to be imported into the petite-mutant mitochondrion (3) and petite mutants can grow on minimal medium, for which some mitochondrial metabolism is required; however, [rho⁰] petite mutants lack mitochondrial DNA, which encodes the apoprotein of cytochrome b, some subunits of cytochrome c oxidase, and the F₁-ATPase (14), and thus are impaired in respiration, mitochondrial ATP generation, and related cellular processes. The [rho⁰] petite mutant was found to be more resistant to LoaOOH than the wild type (Fig. 5), tolerating concentrations threefold higher than the dose of LoaOOH that was lethal for the grande strain under the same conditions (data not shown). This high intrinsic resistance indicates that mitochondrial function plays an important role in eliciting the cytotoxic effect of LoaOOH.

View larger version (16K): [in this window] [in a new window]   FIG. 6.   Inhibition of respiration or ATP synthesis can increase cellular resistance to LoaOOH. (A) Wild-type cells were treated with a range of concentrations of one of the respiratory inhibitors flavone (0.05 to 0.2 mM), antimycin (0.1 to 0.5 mM), KCN (0.1 to 0.5 mM), and sodium azide (0.1 to 0.5 mM) or with an inhibitor of ATP synthesis, oligomycin (0.2 mM), for 1 h prior to treatment with a lethal dose of LoaOOH (0.2 mM). (B) The wild-type strain CY4 (wt grande) and its isogenic coq3 and cox6 mutants (lacking ubiquinone and cytochrome c oxidase subunit 6, respectively) were tested for their sensitivities to LoaOOH as described for Fig. 5. Data are means of triplicates from a representative experiment.

Effect of mutations affecting the respiratory chain on cellular resistance and adaptation to LoaOOH. Ubiquinone-deficient mutants are sensitive to linoleic acid at concentrations higher than those used as controls in this study, possibly due to the subsequent formation of lipid peroxidation products (13). A range of mitochondrial mutants were tested under the conditions for LoaOOH treatment previously described. These included the coq3 mutant (which lacks ubiquinone), the cox6 mutant (which lacks cytochrome oxidase subunit 6), and the atp2 mutant (which lacks the  subunit of the mitochondrial F₁-ATPase). The effect of each mutation was compared to results for both the isogenic wild type and the isogenic [rho⁰] petite mutant, since all of the above nuclear pet mutants are phenotypically petite. In the CY4 strain background, mutations of cox6 and coq3 led to increased resistance approaching that of the [rho⁰] petite mutant (Fig. 6B). These results agree with those obtained with the respiration inhibitors. In the W303-1B background, the atp2 mutant gave results similar to those for the isogenic coq3 mutant and the [rho⁰] petite mutant (data not shown), and these were in agreement with the result obtained with oligomycin. Inhibition of mitochondrial ATP synthesis also led to resistance to the toxic effects of LoaOOH. The results described above indicate that mitochondrial function(s) associated with respiration is needed to elicit full toxicity of LoaOOH. One possibility is that reduced cytochrome c oxidase can donate an electron to LoaOOH and that, in the presence of oxygen, a lipid peroxy radical is formed which can initiate the chain reaction of lipid peroxidation. This is supported by the oxygen effect on sensitivity. The intrinsic resistance of the coq3 and cox6 mutants, which is similar to that of the [rho⁰] petite mutant, also supports this hypothesis.