Maturation-Dependent Vulnerability of Oligodendrocytes to Oxidative Stress-Induced Death Caused by Glutathione Depletion

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The Journal of Neuroscience, August 15, 1998, 18(16):6241-6253

Maturation-Dependent Vulnerability of Oligodendrocytes to Oxidative Stress-Induced Death Caused by Glutathione Depletion
Stephen A. Back, Xiaodong Gan, Ya Li, Paul A. Rosenberg, and Joseph J. Volpe
Department of Neurology, Children's Hospital and Harvard Medical School, Boston, Massachusetts 02115

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Death of oligodendrocyte (OL) precursors can be triggered in vitro by cystine deprivation, a form of oxidative stress thatinvolves depletion of intracellular glutathione. We report herethat OLs demonstrate maturation-dependent differences in survivalwhen subjected to free radical-mediated injury induced by glutathionedepletion. Using immunopanning to isolate rat preoligodendrocytes(preOLs), we generated highly enriched populations of preOLs andmature OLs under chemically defined conditions. Cystine deprivationcaused a similar decrease in glutathione levels in OLs at bothstages. However, preOLs were completely killed by cystine deprivation,whereas mature OLs remained viable. Although the glutathione-depletingagents buthionine sulfoximine and diethylmaleate were more potentin depleting glutathione in mature OLs, both agents were significantlymore toxic to preOLs. Glutathione depletion markedly increasedintracellular free radical generation in preOLs, but not in matureOLs, as indicated by oxidation of the redox-sensitive probe dihydrorhodamine123. The antioxidants $alpha$ -tocopherol, idebenone, and glutathionemonoethylester prevented the oxidation of dihydrorhodamine incystine-depleted preOLs and markedly protected against cell death.When the intracellular glutathione level was not manipulated,preOLs were also more vulnerable than mature OLs to exogenousfree radical toxicity generated by a xanthine-xanthine oxidasesystem. Ultrastructural features of free radical-mediated injuryin glutathione-depleted preOLs included nuclear condensation,margination of chromatin, and mitochondrial swelling. These observationsindicate that preOLs are significantly more sensitive to the toxiceffects of glutathione depletion and that oligodendroglial maturationis associated with decreased susceptibility to oxidative stress.

Key words: oligodendrocyte; glutathione; cystine; free radicals; oxidative stress; growth factor

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Periventricular leukomalacia (PVL) is a lesion of the periventricular cerebral white matter that has its peak incidence inthe premature infant and underlies the subsequent developmentof cerebral palsy and cognitive impairment (Volpe, 1995). PVLis initiated by cerebral ischemia as a consequence of the presencein the white matter of vascular end zones and of the occurrencein the premature infant of a pressure-passive circulation (Volpe,1997). Impaired myelination is the principal pathological sequelaof PVL (Rorke, 1992), a finding supported by brain imaging studiesfrom clinically affected children (Flodmark et al., 1989; vande Bor et al., 1989).

Definition of the specific oligodendrocyte (OL) developmental stage when the vulnerability to injury is greatest would bea critical advance in the understanding of PVL but has been hamperedby the lack of a suitable model system. We sought here to accountfor the propensity of PVL to occur in the premature infant bydetermining whether OLs demonstrate maturation-dependent differencesin susceptibility to death induced by oxidative stress. We choseto study oxidative stress, because PVL is related to cerebralischemia, and ischemia and reperfusion is well established tolead to generation of injurious oxygen free radicals (Hill, 1991;Traystman et al., 1991; Kelly, 1993). Thus, we developed an invitro system to study two distinct OL maturational stages, thepreoligodendrocyte (preOL) and the mature OL. The availabilityof stage-specific antibodies, developed against an array of sequentiallyexpressed OL cell surface and myelin-specific glycolipids andglycoproteins (for review, see Pfeiffer et al., 1993), enabledus to isolate highly enriched populations of preOLs by immunopanning(Gard et al., 1993). The preOL, derived from A2B5 monoclonal antibody-positiveOL progenitors, is the mitotically active premyelinating precursorto the mature myelin basic protein (MBP)-positive OL and is identifiedby immunoreactivity to the O4 but not the O1 monoclonal antibody(Pfeiffer et al., 1993; McMorris and McKinnon, 1996). The long-termmaintenance of OLs was achieved using growth factors, includingplatelet-derived growth factor (PDGF), basic fibroblast growthfactor (bFGF), and ciliary neurotrophic factor (CNTF), which promotetheir in vitro survival, proliferation, or differentiation (Barresand Raff, 1994).

We recently reported that cystine deprivation induced the death of a mixed population of OL precursors via a form of oxidativestress induced by depletion of intracellular glutathione (Yonezawaet al., 1996). These studies were conducted in a serum-containingsystem in which the dependence on cystine for OL survival couldbe prevented by a diffusible factor released by astrocyte-richmixed glial cultures. The present study characterized the intrinsicvulnerability of OLs to death triggered by oxidative stress atdefined maturational stages in a chemically defined system inwhich the extrinsic effects of serum- and glial-derived factorswere eliminated. We found that preOLs and mature OLs displayedmaturation-dependent differences in susceptibility to death causedby glutathione depletion.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Oligodendrocyte cultures. Primary cultures of O4+O1 $-$ preOLs were prepared from the cerebral hemispheres of 4-d-old SpragueDawley rats according to the immunopanning protocol of Gard etal. (1993). The isolated preOLs (2 × 10⁴) were seeded in 50 µl droplets of DMEM/Hepes-buffered Earle'sbalanced salt solution (1:1) on coverslips (12 mm in diameter)(633029; Carolina Biological Supply, Burlington, NC) coated with50 µg/ml poly-D-ornithine (P-0546; Sigma, St. Louis, MO). Fivecoverslips in a 35 mm diameter dish were incubated for 30 minat 36°C in a humidified CO₂ incubator (95% air-5% CO₂), afterwhich 2 ml of a serum-free basal defined medium (BDM), preparedas previously described (Gard et al., 1993), was added to thedish. Cystine-containing BDM was prepared using cystine-free DMEM(custom formula 96-0214DJ; Life Technologies, Grand Island, NY).To generate cultures greatly enriched in either preOLs or matureOLs (see Results), the basal medium was supplemented every 72hr, including at the time of plating, with selected combinationsof growth factors: (1) 10 ng/ml PDGF AA and bFGF for 3 or 8 dafter plating; (2) 10 ng/ml CNTF, 5 µM forskolin, and 15 nM 3,3',5-Triido-L-thyronine(T₃) for 8 d after plating; or (3) 10 ng/ml PDGF AA and bFGF forthe first 8 d after plating, followed by an 8 d supplementationwith 10 ng/ml CNTF, 5 µM forskolin, and 15 nM T₃. PDGF AA, bFGF,CNTF, and NT-3 were from Peprotech (Princeton, NJ).

Immunocytochemical characterization of oligodendroctyes. The mouse monoclonal antibodies A2B5, O4, and O1 (1:50) were visualizedin live cultures using fluorescein-conjugated (µ-chain-specific)IgM (Vector Laboratories, Burlingame, CA) as secondary antisera(Bansal et al., 1989). The O4 and O1 antibodies were preparedusing hybridoma cells, which were the generous gift of Dr. StephenPfeiffer (University of Connecticut Health Center, Farmington,CT). Mouse monoclonal antibodies against MBP (1:100) (BoehringerMannheim, Indianapolis, IN) and glial fibrillary acidic protein(GFAP; 1:400) (Sigma) were localized using cultures fixed for10 min at room temperature in 4% formaldehyde in HBSS before immunocytochemistry.Anti-MBP and anti-GFAP antibodies were visualized with fluorescein-conjugatedgoat anti-mouse IgG (Vector).

Quantitative characterization of the distributions of OL maturational stages generated by particular culture conditions wasdetermined in a minimum of three experiments. At least 10 20×fields (>1000 cells) were counted using a Nikon epifluorescentmicroscope to quantify the number of cells labeled by each antibody.Coverslips were mounted in Fluoromount-G (Southern Biotechnology,Birmingham, AL) containing 0.5 µg/ml Hoechst 33258 (Sigma) preparedas a 5 mg/ml stock solution in water. Total cell number or nuclearcondensation associated with cell death were determined by visualizingnuclei labeled with Hoechst 33258.

Quantification of viable cells. Survival of cells was determined after 24 hr, unless otherwise indicated, by using Alamarblue (AB) (AccuMed International, Westlake, Ohio) as an indexof viability (McGahon et al., 1995). The assay solution was preparedby diluting a 100× stock solution of AB into Earle's balancedsalt solution (EBSS) (14015-028; Life Technologies). Aliquotsof 300 µl of assay solution were transferred to 24-cell well platesand warmed to 36°C in a humidified CO₂ incubator before use. Coverslipswere incubated in the assay solution for 2 hr, unless otherwiseindicated. The fluorescence of the assay solution (1:50 in EBSS)was measured (excitation at $lambda$ = 560 nm; emission at $lambda$ = 590 nm)with a Hitachi F-2000 fluorescence spectrophotometer. The incubationtime for AB exposure produced a value that was no less than fivetimes greater than background and yielded an increase in fluorescencethat was linear over the duration of the assay.

Glutathione measurement. Total glutathione was determined by using a previously described kinetic assay (Tietze, 1969). Themedium was aspirated, and the cultured cells were washed twicewith HBSS. Perchloric acid (0.3 M, 200 µl) was added to each coverslipand incubated for 15 min on ice with gentle shaking. The perchloricacid solution was transferred to a 1.5 ml microcentrifuge tubeand adjusted to pH 7.6 with 3 M potassium bicarbonate (20-25 µl).After a 30 min incubation on ice, the solution was centrifugedat 14,000 rpm for 5 min at 2-4°C. For determination of glutathionecontent, 50 µl of the supernatant solution was added to a 96-cellwell plate containing the following: 50 µl of vehicle solutioncontaining 0.3 M perchloric acid adjusted to pH 7.6 with 3 M potassiumbicarbonate, 50 µl of 2.4 mM 5,5'-dithiobis-2-nitrobenzoic acid(D-8130; Sigma), and 50 µl of 40 µg/ml glutathione reductase (BoehringerMannheim) in 0.1 M sodium phosphate buffer (pH 7.6) with 5 mMEDTA. Immediately after adding 50 µl of 0.8 mM NADPH (N-1630;Sigma), the initial rate of reaction at 25°C was determined fromthe change of absorbance at 405 nm measured every 15 sec overthe first 6 min of the reaction (Thermomax microplate reader;Molecular Devices, Sunnyvale, CA). Total glutathione content (reducedand oxidized) was determined in reference to a standard curve.Protein content was determined by a Micro BSA protein assay kit(Pierce, Rockford, IL).

Glutathione depletion studies. For cystine deprivation studies, dishes containing five coverslip cultures were routinely washedonce in 2 ml of cystine-depleted medium immediately before transferto experimental medium (2 ml) to remove excess cystine derivedfrom the culture medium. Buthionine sulfoximine (BSO) (B2640;Sigma) and diethylmaleate (DEM) (M5887; Sigma) 10 mM stock solutionswere freshly prepared in BDM. Cultures were exposed to 2 ml ofmedium containing BSO or DEM. Glutathione monoethylester (G1404;Sigma) was prepared as a 100 mM stock solution in sterile 50 mMPBS, pH 7.4, which was stored at $-$ 80°C until use.

Free radical scavengers. Idebenone (Takeda Chemical Industries, Osaka, Japan) and $alpha$ -tocopherol were prepared as 1 mM stocksolutions in DMSO and stored at $-$ 20°C until they were directlyadded to the experimental medium.

Fluorescence imaging by confocal microscopy. Dihydrorhodamine 123 (D-632; Molecular Probes, Eugene, OR) was prepared as a10 mM stock solution in DMSO and stored at $-$ 20°C. Cells were loadedin medium containing 5 µM dihydrorhodamine 123 at 36°C in a 5%CO₂ incubator for 20 min before microscopy. After loading, thecells were briefly washed twice in HBSS and immediately visualizedusing either a Zeiss Microphot epifluorescent microscope or alaser scanning confocal microscope (Noran Instruments), with anargon-ion laser coupled to an inverted microscope (Nikon Diaphot200) and equipped with a 40× oil-immersion objective (Nikon PlanFluor, 1.30 NA). Cells loaded with dihydrorhodamine were visualizedby excitation at $lambda$ = 490 ± 15 nm light using a rhodamine long-passfilter, and fluorescence emission was detected at $lambda$ > 515 nm.The beam was attenuated using a 15 nm dichroic confocal aperture.In all experiments, laser settings, including brightness, contrast,and exposure time (100 nsec), were held constant. Frame-averagedconfocal images (32 per image) were digitalized at 512 × 480 pixelsusing microcomputer-based imaging software (Noran OZ with Intervision).For analysis of cellular fluorescence intensity, regions of interestwere selected to include oligodendroglial cytoplasm but to excludethe nucleus. Values reported represent the average of mean pixelintensities determined from comparable numbers of cellular profiles(>50) for all conditions.

Exogenous free radical toxicity studies. Superoxide anion was generated using xanthine (X-0626; Sigma) and xanthine oxidase(X-1857; Sigma). Xanthine was freshly prepared in experimentalmedium and diluted to a final concentration of 50 µM. Exposureof OL cultures to superoxide anion was initiated by the additionof xanthine oxidase (5 mU/ml) to the xanthine-containing medium.

Ultrastructural characterization of OL tissue cultures. Six coverslip cultures of preOLs exposed for 14.5 hr to cystine-containingor cystine-depleted medium were fixed and processed for electronmicroscopy using a protocol identical to that described previously(Rosenberg and Harris, 1993). A minimum of 50 separate regionswere sampled from two separate coverslips per condition and photographedin a JEOL 1200 EX electron microscope.

Statistical analysis. Unless otherwise noted, all experiments were replicated three times, and all values were derived frommeasurements done in triplicate. Significance for multiple comparisonswas determined by one-way ANOVA with post hoc comparison by Student-Newman-Keulsmultiple comparisons test using the Instat 2 computer program(Graph Pad Software, San Diego, CA) or by factorial ANOVA usingSAS version 6.12 (SAS Institute, Cary, NC). The Student's t testwas used for comparison of two conditions. In the text, dispersionin single experiments is indicated by the SD and in pooled databy the SEM. Survival data are presented as the percentage of viablecells compared with control cultures.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Production of preOLs and mature OLs in culture

To determine whether OLs display maturation-dependent differences in survival in response to cystine deprivation, we firstsought to establish culture conditions to generate highly enrichedpopulations of preOLs or mature OLs. We evaluated the effectsof selected combinations of growth factors on O4+O1 $-$ preOLs isolatedby immunopanning (see Materials and Methods). We first characterizedcells grown in the presence of preOL medium that consisted ofmedium supplemented with 10 ng/ml bFGF and PDGF AA. These growthfactors have been shown to promote the preOL phenotype (Bogleret al., 1990; McKinnon et al., 1990; Huber et al., 1994). After3 d in culture, the majority of cells were apparent OL progenitorsthat displayed an immature phenotype characterized by cells witha bipolar morphology. Immunocytochemical characterization withmonoclonal antibodies directed to OL cell surface epitopes confirmedthat most of these cells were OL progenitors but with some preOLspresent; 91 ± 3% stained with the A2B5 antibody, and 21 ± 8% stainedwith the O4 antibody (Fig. 1). After 8 d in culture, large numbersof preOLs were generated. Most cells displayed a more mature phenotypecharacterized by cells with a simple multipolar morphology. Themajority (83 ± 6%) stained with O4 antibody. A minority of thecells (23 ± 10%) stained with O1 antibody. Contamination by astrocytesin 8-d-old cultures was 5.6 ± 2.8% (n = 4).

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Figure 1. Quantitative immunocytochemical characterization of cultures generated when preOLs were maintained for 3 or 8 d in preOL medium or 8 d in mature OL medium. Immunocytochemical characterization of sister coverslips was done using the four monoclonal antibodies indicated. Values represent the mean ± SD from three separate experiments. Ten 20× fields (>1000 cells) were counted on one coverslip per condition in each experiment. Total cell number was determined by counting all cells labeled with Hoechst 33258 (see Materials and Methods).

We tested the response of preOLs to a mature OL medium, which consisted of BDM supplemented with 10 ng/ml CNTF, 15 nM T₃,and 5 µM forskolin. After 8 d in culture, a greatly enriched populationof mature OLs was generated (Fig. 1). Most cells elaborated extensivesheets of membrane that stained for MBP. Immunocytochemical characterizationconfirmed that the majority of these cells were mature MBP-positiveOLs (91 ± 1%) (Fig. 1).

Maturation-dependent difference in OL dependence on cystine for survival

We next asked whether preOLs and mature OLs displayed a difference in their response to oxidative stress induced by cystinedeprivation. A clear dependence of preOLs on cystine for survivalwas shown by a 24 hr exposure to medium containing varying concentrationsof cystine (Fig. 2A). Loss of cell viability in cystine-depletedmedium was quantified by a sensitive fluorescent assay that measuredthe decrease in metabolism of the proprietary formazan dye AB(see Materials and Methods). Figure 2A shows that AB fluorescencewas a direct measure of preOL death under conditions of oxidativestress. When cells were exposed to varying concentrations of cystine,there was no significant difference in the EC₅₀ for OL viability,as determined using either AB or trypan blue (TB) (Perry et al.,1997) (Fig. 2A) or the MTT assay (Mosmann, 1983) (data not shown).In six experiments, the EC₅₀ for cystine, determined by usingAB, ranged from 0.5 to 35 µM, with an EC₅₀ of 2 ± 2 µM for fiveof these experiments. In three experiments, the EC₅₀ for cystine,determined by using TB, ranged from 0.2 to 6 µM, with an EC₅₀of 3.1 ± 2.9 µM.

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Figure 2. A, AB is a direct measure of OL viability. Dose-response curves of preOL survival as a function of the concentration of cystine in the culture medium were compared using AB or cell counts with TB. In this experiment the EC₅₀ for cystine was 3 µM, as determined by AB or TB. B, PreOLs are markedly more vulnerable to cystine deprivation than mature OLs. The survival of preOLs was 2 ± 0.3 versus 76 ± 14% for the mature OLs.

When the 24 hr survival of preOLs and mature OLs in cystine-depleted medium was compared, preOLs were almost completely killed,whereas mature OLs were largely viable. The cystine-deprived preOLshad a survival of 2 ± 0.3% compared with 76 ± 14% for the matureOLs (Fig. 2B). In eight separate experiments, the mean 24 hr survivalof preOLs in cystine-depleted medium was 3 ± 1% of control (p< 0.001). In contrast to preOLs, mature OLs in 10 separate experimentsshowed a much greater viability of 87 ± 3% of control (p < 0.005)when exposed to cystine-depleted medium for 24 hr (Fig. 2B).

Survival of mature OLs is independent of cell density and previous history of growth factor exposure

We next considered that the enhanced survival of mature OLs in cystine-depleted medium might be related to the conditionsunder which the cells were grown. We first investigated the effectof cell density on the survival of mature OLs. PreOLs culturedin the presence of PDGF and bFGF were mitotically active; therefore,cell number continuously increased after plating. However, matureOLs were of much lower density, because they were generated fromcultures that expanded more slowly in the mature OL medium. Toassess the effect of increased cell density on mature OL survival,we generated mature OLs at a density comparable to or greaterthan that of preOLs grown for 8 d. This was accomplished by culturingpreOLs for 8 d in preOL medium. Thereafter, from day 9-16 in culture,bFGF and PDGF were withdrawn, and the preOLs were supplementedevery 72 hr with the mature OL medium. This protocol generateda more dense population of mature OLs that were immunocytochemicallysimilar to the lower density cultures of mature OLs (data notshown). Figure 3A shows the results of a representative experimentdemonstrating that an increase in cell density did not decreasethe survival of mature OLs after a 24 hr exposure to cystine-depletedmedium. The average 24 hr survival of the higher density cultureswas 95 ± 2% of control (n = 10). Unless otherwise noted, matureOLs generated by this protocol were used in all subsequent experiments.

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Figure 3. A, Cell density has no effect on the survival of mature OLs in cystine-depleted basal defined medium (CYS-). Survival of preOLs was also determined to confirm the relative toxicity of the cystine-depleted medium to the two OL stages. Mature OLs were generated at low density (LD) or high density (HD), as described in Materials and Methods. Values are expressed as the corrected fluorescent emission at 595 nm of the reaction product generated after a 2 hr incubation in AB. In this experiment, the survival of the preOLs was 2 ± 0.4%. The survival of the mature OLs at low density was 76 ± 14%, and survival was 99 ± 6% for the mature OLs at high density. B, Lack of effect of previous history of growth factor exposure on the survival of low-density mature OLs in cystine-depleted medium (CYS-). The survival of mature OLs generated by continuous exposure of preOLs to mature OL medium for 9 d (Mature OL Medium) did not differ from control. The survival of mature OLs, generated by a 7 d exposure of preOLs to mature OL medium, followed by a 2 d exposure to preOL medium (PreOL Medium), did not differ from control.

Another potential explanation for the difference in viability of preOLs and mature OLs was an effect on viability mediatedby one or more of the growth factors to which the cells were exposedduring culture. We reasoned that if the enhanced vulnerabilityof preOLs to cystine deprivation was conferred by the growth factorswith which they were generated (i.e., PDGF and bFGF), then exposureto these same growth factors might also decrease the survivalof cystine-deprived mature OLs. This was assessed by exposinglow-density 7-d-old cultures of mature OLs (i.e., with no previousexposure to bFGF or PDGF) to preOL medium (containing bFGF andPDGF) for 48 hr. The effect of cystine deprivation on the survivalof 9-d-old cultures of mature OLs exposed only to the mature OLmedium did not differ, however, from the effect on the 9-d-oldcultures of mature OLs that had previous exposure to preOL medium(Fig. 3B). A lack of effect of previous exposure to PDGF and bFGFon the survival of mature OLs was further supported by the observationthat the higher density cultures of mature OLs remained largelyviable in cystine-depleted medium, despite their previous historyas preOLs exposed continuously for 8 d to PDGF and bFGF (Fig.3A). PreOLs were also equally vulnerable to cystine deprivationwhen tested in the presence or absence of the growth factors thatstimulated their proliferation (i.e., PDGF and bFGF) (data notshown). Hence, regardless of the timing of exposure to PDGF andbFGF, mature OLs retained their resistance to the toxicity ofcystine deprivation.

Cystine deprivation induces glutathione depletion in preOLs and mature OLs

We next asked whether the difference in viability of preOLs and mature OLs might be attributable to a difference in the glutathionedepletion resulting from cystine deprivation. In three separateexperiments, this was assessed by serial measurements of the viabilityand total glutathione content of preOLs and mature OLs duringa 24 hr exposure to cystine-depleted medium (Fig. 4). Figure 4Aindicates that preOLs significantly declined in viability within12 hr and were completely killed within 24 hr, whereas the viabilityof mature OLs did not differ from control. Figure 4B shows thatpreOLs and mature OLs had a similar rate of glutathione depletion.In three experiments, the glutathione content of mature OLs at24 hr (0.5 ± 0.1 ng/µg protein) did not differ significantly fromthat of preOLs after 12 hr (0.9 ± 0.2 ng/µg protein). In the experimentshown, glutathione in the mature OLs decreased to 11 ± 3% of controlat 24 hr compared with a decrease to 14 ± 2% of control in thepreOLs at 12 hr. It is noteworthy that although the glutathionelevel at 12 hr in the preOLs was associated with their eventualdeath, a similar level in the mature OLs at 24 hr was associatedwith minimal loss of viability.

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Figure 4. PreOLs are markedly more vulnerable to cystine deprivation than mature OLs, despite a similar time course for glutathione depletion. The time course of survival of preOLs and mature OLs in cystine-containing or cystine-depleted medium (A) was compared relative to the glutathione content of parallel cultures treated with the same conditions (B). After the indicated exposure times, viability was assayed with AB or glutathione was extracted and assayed. A, PreOLs were completely killed after a 24 hr exposure to cystine-depleted medium. There was no difference in viability at 24 hr for mature OLs in cystine-depleted medium relative to preOLs or mature OLs in cystine-containing medium. B, There was no difference in the decrease in glutathione content of preOLs and mature OLs after a 12 hr exposure to cystine-depleted medium. The glutathione content of the preOLs at 12 hr was 0.7 ± 0.1 ng/µg protein and did not differ significantly from that of mature OLs at 24 hr (0.5 ± 0.1 ng/µg protein). The glutathione content of preOLs at 24 hr is not shown, because it could not be determined due to complete cell death. Statistical comparisons were by factorial ANOVA.

It has been proposed that OLs in vitro may be more vulnerable to death induced by oxidative stress than are astrocytes becauseof a lower basal glutathione content (Thorburne and Juurlink,1996). We found, however, that the basal glutathione level ofpreOLs was significantly higher than that of mature OLs. The basalglutathione level of preOLs was 5.0 ± 0.4 (n = 8) versus 3.2 ±0.2 ng/µg protein (n = 9) for mature OLs (mean ± SE; p = 0.002).Hence, a higher basal glutathione level did not confer on preOLsgreater protection against the toxicity of cystine deprivation.

Effect of glutathione-depleting agents on viability and glutathione levels of mature OLs

Because mature OLs were more viable than preOLs under conditions of low glutathione (Fig. 4), we next asked whether this resistanceto the toxic effects of glutathione depletion might also be seenwhen mature OLs were treated with agents that pharmacologicallydepleted intracellular glutathione. We tested BSO, an inhibitorof glutathione synthetase (Griffith, 1982), and DEM, which irreversiblyconjugates glutathione and other thiol-containing compounds (Plummeret al., 1981). Figure 5A is representative of the results of twodose-finding experiments that compared the effect of a 24 hr exposureto increasing concentrations of BSO on the viability and glutathionecontent of mature OLs. At 10 µM, BSO maximally depleted glutathionebut had no effect on cell viability. Figure 5B is representativeof three dose-finding experiments that compared the effect onthe viability and glutathione content of mature OLs of a 24 hrexposure to increasing concentrations of DEM. Progressive declinein the glutathione content of the mature OLs was not associatedwith significant loss of mature OL viability. At 100 µM DEM, theviability of mature OLs was 70 ± 12% of control (NS), despitedepletion of glutathione to 0.2 ± 0.03 ng/µg protein. Significanttoxicity was observed at 1 mM DEM.

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Figure 5. Mature OLs are largely resistant to the toxicity of the glutathione-depleting agents BSO (A) or DEM (B). Dose-response curves compare the survival and glutathione content of mature OLs as a function of the concentration of BSO or DEM. Parallel cultures were exposed for 24 hr to BSO or DEM, after which they were assayed for viability with AB, or glutathione was extracted and assayed. A, There was no significant loss of viability at any concentration of BSO tested relative to control. The EC₅₀ for the effect of BSO on the glutathione content of the mature OLs was 0.25 µM. B, The viability at 100 µM DEM was 70 ± 12% of control (NS), and the glutathione content was 0.2 ± 0.03 ng/µg protein. The glutathione content of the cells at 1 mM DEM could not be determined because of complete cell death. Statistical comparisons were by factorial ANOVA.

Relative effect of glutathione-depleting agents on the viability of preOLs versus mature OLs

Because cystine deprivation was primarily toxic to preOLs, we next determined whether BSO and DEM might also be more toxicto preOLs than to mature OLs. BSO was significantly more toxicto preOLs (Fig. 6A), and in this experiment, the EC₅₀ for thetoxicity of BSO to preOLs was 290 µM. The EC₅₀ for the toxicityof BSO to preOLs was 275 ± 20 µM in two separate experiments.By contrast, in this and five additional experiments, we foundthat BSO had no significant effect on the viability of matureOLs at concentrations <3 mM. At 10 mM BSO, complete loss of viabilitywas observed in only four of eight experiments (Fig. 6A).

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Figure 6. PreOLs are more vulnerable to the toxicity of BSO (A) or DEM (B), despite the fact that these agents more potently deplete glutathione in mature OLs (C, D). A, The EC₅₀ for the toxicity of BSO to preOLs was 290 µM and to mature OLs was 3.3 mM. B, The EC₅₀ for the toxicity of DEM to preOLs was 17 µM and to mature OLs was 103 µM. For the glutathione measurements, glutathione was extracted after an 8 hr exposure to BSO (C) or a 4 hr exposure to DEM (D), at which times there was no loss of cell viability, as described in Results. In this experiment, the EC₅₀ for the effect of BSO on the glutathione content of the preOLs was 2.1 µM and on the mature OLs was 0.5 µM. The EC₅₀ for the effect of DEM on the glutathione content of the preOLs was 33 µM and on the mature OLs was 5.2 µM. Similar results were obtained in one additional experiment.

Figure 6B shows a representative experiment in which DEM was also found to be markedly more toxic to preOLs than to matureOLs. The EC₅₀ for the toxicity of DEM to the preOLs was 17 µMversus an EC₅₀ of 103 µM for the mature OLs. The EC₅₀ for thetoxicity of DEM to preOLs ranged from 14 to 80 µM and was 17 ±3 µM for three of four experiments. The EC₅₀ for the toxicityof DEM to mature OLs ranged from 103 to 333 µM and was 148 ± 43µM for five of six experiments.

Relative effect of glutathione-depleting agents on glutathione levels in preOLs and mature OLs

We next asked whether the enhanced toxicity of BSO and DEM to preOLs might be attributable to a difference in the efficacyof the effect of these agents on glutathione depletion in preOLs.To accurately measure glutathione depletion within preOLs, itwas first necessary to determine whether a period of exposureto BSO or DEM could be identified when the total glutathione contentwas maximally depleted but when no significant loss of cell viabilityoccurred. We found that these conditions were met by an 8 hr exposureto 200 µM BSO or a 4 hr exposure to 100 µM DEM (data not shown).Figure 6C,D is representative of two experiments that comparedthe effect of an 8 hr exposure to BSO or a 4 hr exposure to DEMon the glutathione level of preOLs and mature OLs. Both BSO andDEM were actually found to deplete glutathione more potently inmature OLs. The EC₅₀ value for glutathione depletion by BSO was2.1 µM for the preOLs compared with 0.5 µM for the mature OLs.The EC₅₀ value for glutathione depletion by DEM was 33 µM forthe preOLs compared with 5.2 µM for the mature OLs. In the twoseparate experiments, the mean EC₅₀ value for glutathione depletionby BSO was 6.1 ± 5.6 µM for the preOLs versus 0.7 ± 0.3 µM forthe mature OLs. The EC₅₀ for glutathione depletion by DEM was30 ± 4 µM for the preOLs versus 5.0 ± 0.3 µM for the mature OLs(p < 0.05). In three additional experiments, a 24 hr exposureto BSO was also more potent in depleting glutathione in matureOLs. The mean EC₅₀ value for glutathione depletion by BSO was2.2 ± 0.1 µM for the preOLs compared with 0.2 ± 0.03 µM for themature OLs (p < 0.001). Glutathione depletion in the preOLs andmature OLs could not be reliably determined after a 24 hr exposureto DEM because of high dose toxicity and resulting cell loss.In summary, despite the fact that preOLs were more vulnerableto the toxicity of glutathione depletion, BSO and DEM were morepotent in depleting glutathione in mature OLs than in preOLs.

Effect of glutathione depletion on free radical generation in preOLs versus mature OLs

We next asked whether the decreased viability of preOLs in response to glutathione depletion might be related to increasedfree radical generation, as assessed by oxidation of dihydrorhodamine123 to the cationic fluorescent probe rhodamine 123 (Rh 123).When we compared the oxidation of dihydrorhodamine 123 by preOLsand mature OLs exposed to cystine-depleted medium, there was amarked increase in Rh 123 fluorescence in preOLs that was observedthroughout the cultures after more than a 12 hr exposure (Fig.7A). Visualization of Rh 123 fluorescence by confocal laser microscopyrevealed that the probe was heavily concentrated within the cytoplasm(Fig. 7B). Figure 7C shows a representative experiment in whichthe magnitude of the increase in Rh 123 fluorescence in preOLsand mature OLs exposed to cystine deprivation was quantitatedby confocal laser microscopy (see Materials and Methods). Aftera 15 hr exposure to cystine-depleted medium, preOLs had a 3.9-foldincrease in Rh 123 compared with control. In seven separate experiments,preOLs displayed a 4.6 ± 0.8-fold increase in Rh 123 relativeto control (p < 0.001). In contrast, in three separate experimentsmature OLs, after periods of cystine deprivation up to 22 hr,showed no significant increase in fluorescence relative to controlpreOLs or control mature OLs. We also detected no significantRh 123 fluorescence in either untreated preOLs or mature OLs culturedin cystine-containing medium (data not shown), suggesting thatthere was no apparent difference in the basal levels of intracellularreactive oxygen species (ROS) in OLs at either stage.

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Figure 7. Free radical generation, assessed by Rh 123 fluorescence, is greatly increased in cystine-deprived preOLs but not in mature OLs. A, Low-power fluorescent photomicrograph showing numerous Rh 123 fluorescent preOLs after a 15 hr exposure to cystine-depleted medium. B, Laser confocal digitalized image showing the cytoplasmic distribution of Rh 123 fluorescence in preOLs after a 15 hr exposure to cystine-depleted medium. C, Quantitation of the relative intensity of Rh 123 fluorescence (see Materials and Methods) in preOLs and mature OLs. There was a 3.9-fold increase in Rh 123 fluorescence in preOLs after 15 hr of cystine deprivation (PreOL-) compared with control (PreOL+). Statistical comparisons were among relative fluorescence intensity in control preOLs, control mature OLs, or treated mature OLs relative to treated preOLs. There was no significant increase in Rh 123 fluorescence in control versus treated mature OLs. *p < 0.001.

Free radical scavengers protect preOLs from the toxicity of cystine deprivation

We next tested the hypothesis that if the toxicity of glutathione depletion was mediated by the deleterious effects of intracellularfree radicals, free radical scavengers should prevent the deathof preOLs caused by exposure to cystine-depleted medium. Figure8A is representative of three separate experiments in which both $alpha$ -tocopherol (30 µM) and idebenone (1 µM) completely preventedthe death of preOLs induced by cystine deprivation. Ascorbate(100 µM) failed to protect preOLs (n = 3), and superoxide dismutaseand catalase (10 U/ml) also had no protective effect (n = 3) (datanot shown).

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Figure 8. The free radical scavengers $alpha$ -tocopherol and idebenone protect preOLs against cystine-deprivation (A) via a mechanism downstream of glutathione depletion (B) that suppresses free radical production (C). The relative effect of these free radical scavengers on the viability (A), intracellular glutathione content (B), and relative intensity of Rh 123 fluorescence (C) of preOLs in cystine-depleted medium is shown. Free radical scavengers were added to cystine-depleted medium, and after a 24 hr exposure, parallel cultures were either assayed for viability with AB (A) or glutathione was extracted and assayed (B). Rh 123 fluorescence was quantified after a 15 hr exposure to cystine-depleted medium (C) when preOLs in cystine-depleted medium remained viable. The $alpha$ -tocopherol and idebenone were dissolved in DMSO, and an equivalent amount of DMSO (0.1% of final medium) was added to control cultures. A, The viability of the free radical scavenger-treated cultures differed significantly from cultures in cystine-depleted medium but did not differ significantly from control. *p < 0.05; **p < 0.05. B, Glutathione content was significantly decreased in cultures in cystine-depleted medium, with or without added free-radical scavengers, compared with control. *p < 0.001. C, The relative intensity of Rh 123 fluorescence of preOLs in cystine-depleted medium was increased significantly relative to control cultures or to those treated with either free radical scavenger. *p < 0.001. Statistical comparisons in A-C were by one-way ANOVA.

To determine whether the protective effect of $alpha$ -tocopherol and idebenone was mediated by preventing a decline in intracellularglutathione or by conferring protection distal to the actionsof glutathione, we measured glutathione levels in cultures ofpre-OLs exposed to cystine-depleted medium in the presence ofeither free radical scavenger (Fig. 8B). We found that although $alpha$ -tocopherol and idebenone markedly protected against cell deathin cystine-depleted medium (Fig. 8A), these compounds did notblock the depletion of intracellular glutathione. We next determinedwhether the protective effects of $alpha$ -tocopherol and idebenone weremediated by preventing an increase in free radical generation,as assessed by measuring Rh 123 in preOLs subjected to cystinedeprivation in the presence of either antioxidant. In two separateexperiments, both $alpha$ -tocopherol (30 µM) and idebenone (1 µM) completelyprevented the increase in Rh 123 that was observed in untreatedpreOLs (Fig. 8C).

Glutathione monoethylester rescues preOLs from the toxicity of cystine deprivation or BSO exposure

If the toxicity of cystine deprivation to preOLs was mediated principally by causing a decline in intracellular glutathione,then the toxicity might be prevented by delivery of reduced glutathioneinto the cells. Although reduced glutathione is poorly transportedinto cells, esterified forms of glutathione are effectively takenup (Anderson et al., 1994). We evaluated the ability of glutathionemonoethylester (GMEE) to protect preOLs against the toxicity ofcystine deprivation. Figure 9A is representative of three experimentsin which 1 mM GMEE markedly protected preOLs against the toxicityof a 24 hr exposure to cystine-depleted medium, with a survivalof 72 ± 14%. The mean survival from these three experiments was78 ± 17%. There was no significant toxicity of 1 mM GMEE (datanot shown). To determine whether the protective effect of GMEEwas mediated by preventing an increase in free radical generation,Rh 123 was quantitated in preOLs subjected to cystine deprivation(Fig. 9B). In two separate experiments, 1 mM GMEE completely preventedthe increase in Rh 123 fluorescence that was observed in cystine-deprivedpreOLs.

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Figure 9. GMEE enhances the survival (A) of preOLs exposed to cystine-depleted medium (CYSTINE-) and suppresses free radical production (B) as measured by the relative intensity of Rh 123 fluorescence. Cells were exposed to 1 mM GMEE from the onset of the experiment. A, Survival in the presence of GMEE was 72 ± 14% relative to cultures in cystine-depleted medium. *p < 0.001. B, Treatment with GMEE suppressed Rh 123 fluorescence relative to preOLs exposed to cystine-depleted medium for 15 hr. Statistical comparisons were among relative fluorescence intensity in cystine-depleted medium versus cystine-containing medium (CYSTINE+) or cystine-depleted medium with GMEE. *p < 0.001. There was no significant difference between the GMEE-treated cultures and control (CYSTINE+). Statistical comparisons in A and B were by one-way ANOVA.

The finding that the potency of BSO to deplete glutathione in preOLs was greater than its toxicity (i.e., the EC₅₀ for thetoxicity of BSO was 275 ± 20 µM, whereas the EC₅₀ for glutathionedepletion by BSO was 6.1 ± 5.6 µM) raised the question of whetherthe toxicity of BSO might be mediated through multiple mechanisms.However, if the toxicity of BSO to preOLs were principally mediatedvia a decline in intracellular glutathione, GMEE might preventthe toxicity. In three experiments, 1 mM GMEE markedly protectedpreOLs against exposure to 10 mM BSO, with a mean survival of87 ± 14% (p < 0.001 relative to control or 10 mM BSO).

Maturation-dependent difference in OL vulnerability to xanthine-xanthine oxidase

Having shown a difference in OL vulnerability to glutathione depletion, we next sought to determine whether preOLs were alsomore vulnerable than mature OLs to oxidative stress when glutathionelevels were not manipulated. To test this hypothesis, we examinedthe toxicity of oxygen radicals generated exogenously by xanthine-xanthineoxidase. The superoxide anion generated by this system is convertedinto several oxygen radicals, including hydrogen peroxide andhydroxyl radical (Kuppusamy and Zweier, 1989; Aizenman, 1995).Dose-finding experiments indicated that maximal toxicity to preOLswas achieved with a concentration of xanthine as low as 50 µMand 5 mU/ml xanthine oxidase (data not shown). Under these conditions,the toxicity of xanthine oxidase was significantly greater topreOLs than mature OLs. As shown in Figure 10, the viability ofpreOLs was 14 ± 5%, whereas mature OLs had a significantly greaterviability of 73 ± 1% (p < 0.001). In four experiments, the meanpreOL survival was 19 ± 5 versus 68 ± 2% for mature OLs.

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Figure 10. PreOLs are more vulnerable than mature OLs to oxygen radicals generated by xanthine oxidase. OL viability was assessed 16 hr after exposure to xanthine (50 µM) and xanthine oxidase (5mU/ml), as described in Materials and Methods. The viability of preOLs was 14 ± 5%, whereas mature OLs had a significantly greater viability of 73 ± 1% (p < 0.001). There was no significant difference between mature OLs in the control or treated groups. The survival of the treated preOLs differed significantly from the control preOLs (p < 0.001). Statistical comparisons were by factorial ANOVA.

Ultrastructural features of free radical-mediated toxicity to preOLs

We reported previously that glutathione-depleted immature OLs grown under serum-rich conditions displayed a number of featuresconsistent with death via apoptosis (Back et al., 1995). To furthercharacterize the mechanism of free-radical mediated toxicity topreOLs, we undertook an ultrastructural analysis of preOLs subjectedto cystine-deprivation. After 14.5 hr of exposure to cystine-depletedmedium, cellular profiles of preOLs were captured at progressivestages of degeneration (Fig. 11). In contrast to control cells(Fig. 11A), an early feature of dying cells was margination ofthe chromatin (Fig. 11B). At later stages, chromatin became progressivelymore condensed (Fig. 11C) until the nucleus was reduced in sizeand uniformly filled with chromatin (Fig. 11D). At all stages ofdegeneration, the integrity of the plasma and nuclear membraneswas retained, but a loss of mitochondrial integrity was observed(Fig. 11B,C). In contrast to control preOLs, mitochondria wereuniformly spherical in shape in the cystine-deprived cells, andthe cristae were not visualized. Mitochondria were markedly swollenin the end-stage cells (Fig. 11D).

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Figure 11. Ultrastructural analysis of the morphological changes observed in glutathione-depleted preOLs captured at various stages of degeneration (B-D) after a 14.5 hr exposure to cystine deprivation. A, Control preOL showing the eccentrically situated nucleus with a uniform distribution of chromatin adjacent to the nuclear membrane. The nucleolus (n) is localized at the center of the nucleus. Mitochondria are uniformly distributed and heterogeneous in shape, and the cristae are readily visualized. B, Note the margination and clumping of chromatin and the condensation of the nucleus and nucleolus (n). Mitochondria are uniformly spherical in shape, and the cristae are no longer visualized (arrowheads). C, In this very degenerated cell, the markedly electron-dense chromatin is condensed and marginated along the intact nuclear membrane, and several droplets of condensed chromatin are present within the nucleus. Most of the degenerated mitochondria (arrowheads) are localized to the left of the nucleus, several swollen mitochondria are visible (open arrows), and the plasma membrane is intact. D, In this end-stage cell, the chromatin is extremely condensed within the markedly shrunken nucleus. Several extremely swollen mitochondria are visible (arrowheads). The plasma membrane is intact. Scale bars: A, B, D, 1 µm; C, 2 µm. .

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

We developed a novel tissue culture model system to examine the hypothesis that PVL arises because of a maturation-dependentvulnerability of OL precursors to death induced by oxidative stress(Back and Volpe, 1997). We demonstrated that preOLs, in contrastto mature OLs, displayed increased susceptibility to death associatedwith free radical-mediated injury induced by glutathione depletionor exogenous ROS. These maturation-dependent differences in vulnerabilityto oxidative stress may be significant for the pathogenesis ofPVL, insofar as PVL has its peak incidence in the premature infant(Volpe, 1995, 1997) at a time when OL precursors appear to predominatein the cerebral white matter (Back et al., 1996).

The maturation of OLs correlated with increased resistance to oxidative stress, as supported by the following data: (1) matureOLs were significantly less vulnerable to glutathione depletioncaused by cystine deprivation, BSO, or DEM (Figs. 3-6); (2) despitea greater potency to deplete glutathione in mature OLs, BSO andDEM were less toxic to them (Fig. 6); (3) exposure to ROS generatedby a xanthine-xanthine oxidase system caused significantly lesstoxicity to mature OLs than preOLs (Fig. 10); and (4) mature OLsfailed to generate intracellular ROS under conditions of glutathionedepletion that triggered a marked increase in preOLs (Figs. 7).Moreover, the increased resistance of mature OLs to oxidativestress was observed, despite a lower basal glutathione level inmature OLs than in preOLs and no apparent difference in basalfree radical generation. The basis for the increased resistanceof mature OLs to oxidative stress is unclear but could involveglutathione-dependent mechanisms, because differences in the rateof total glutathione turnover or the depletion of different subcellularglutathione pools might underlie the increased resistance to oxidativeinjury. The fact that cystine deprivation similarly reduced theglutathione content in both OL stages (Fig. 4) supports the persistenceof cystine transport mechanisms in mature OLs that regulate cystineuptake for glutathione synthesis.

The increased vulnerability of the preOL to oxidative stress correlated with a greater dependence on intracellular glutathionefor survival. We found the following: (1) preOLs were more vulnerablethan mature OLs to the same degree of glutathione depletion, whetherit was caused by cystine deprivation, BSO, or DEM; (2) glutathionedepletion caused a marked rise in ROS (Fig. 7), whose toxicitycould be prevented by the antioxidants $alpha$ -tocopherol and idebenone(Fig. 8); and (3) the toxicity of glutathione depletion was preventedby glutathione replacement with glutathione monoethylester (Fig.9). These data point to a critical role for glutathione in preventingROS-mediated injury in preOLs. Because glutathione can preventROS generation through multiple mechanisms, delayed maturationof one or more of these may underlie the increased vulnerabilityof preOLs to glutathione depletion. Glutathione scavenges ROSthrough glutathione peroxidase, a key antioxidant enzyme (Meister,1989; Vina, 1990), conjugates 4-hydroxynonenal, a lipid peroxidationproduct that mediates neuronal apoptosis caused by oxidative stress(Kruman et al., 1997), and suppresses the activity of 12-lipoxygenase,which has been linked to apoptosis of immature cortical neuronsthrough a pathway involving a downstream rise in ROS generationand calcium influx (Li et al., 1997). Maturational differencesin expression of enzymes that regulate glutathione levels couldalso underlie the increased vulnerability of preOLs to glutathionedepletion (Vina, 1990).

It remains unclear whether glutathione depletion alone is sufficient to trigger the death of preOLs. That glutathione depletionis necessary for preOL death is supported by the protection renderedby GMEE to cystine-deprived preOLs (Fig. 10). Despite the factthat the potency of BSO and DEM to deplete glutathione was greaterthan their potency to produce toxicity, BSO toxicity also appearedto be mediated through glutathione depletion, because GMEE rescuedpreOLs from BSO-induced death. One explanation for the disparitybetween the potency of BSO and DEM to deplete glutathione andtheir toxicity may be that these agents less effectively depletemitochondrial glutathione (Meredith and Reed, 1982; Griffith andMeister, 1985). Because mitochondrial glutathione derives fromthe cytosolic pool (Griffith and Meister, 1985) and has a muchlonger half-life than cytosolic glutathione (Meredith and Reed,1982), BSO and DEM may not be toxic to preOLs except at higherconcentrations that effectively deplete the mitochondrial pool.

Although the susceptibility of preOLs to glutathione depletion appears related to intracellular ROS generation, the mechanismby which glutathione depletion triggers a rise in ROS is presentlyunclear. The source of the ROS detected by Rh 123 could not bedetermined. Although Rh 123 selectively accumulates in mitochondria,there are multiple potential sites of production of this probe(Royall and Ischoropoulos, 1993; Dugan et al., 1995). Our datasuggest that ROS generation is a late event that follows a fallin glutathione, because we were unable to detect a rise in Rh123 fluorescence until at least 12 hr of cystine deprivation (datanot shown), at which time glutathione was approaching its nadir(Fig. 4). Primary embryonic cortical neurons also showed an apparentlate rise in ROS when depleted of glutathione (Li et al., 1997).Notably, when thymocytes were triggered to undergo apoptosis byseveral different means, ROS production and cytosolic calciuminflux also ensued as late events that followed glutathione depletionand loss of the mitochondrial membrane potential (Macho et al.,1997). Hence, one mechanism by which glutathione depletion maytrigger ROS production in preOLs may be through an alterationin mitochondrial function. A role for glutathione in mitochondrialfunction is supported by the following: (1) activation of themitochondrial permeability transition appeared to correlate withthe level of endogenous oxidized glutathione (Chernyak and Bernardi,1996); (2) glutathione depletion reduced the activity of the mitochondrialrespiratory enzyme complexes I, II-III, and IV (Bolanos et al.,1996); (3) the mitochondrial protein Bcl-2 decreased ROS generationin glutathione-depleted neural cells (Kane et al., 1993); and(4) overexpression of Bcl-2 resulted in a higher basal glutathionelevel and a failure to deplete glutathione in response to an apoptoticsignal, whereas bax overexpression correlated with a reductionin basal glutathione level (Ellerby et al., 1996; Bojes et al.,1997).

The ultrastructural studies presented here (Fig. 11) begin to address the mechanism of preOL death caused by glutathione depletion.The margination and condensation of chromatin, decrease in nuclearsize, vacuolation of the cytoplasm, and preservation of the plasmamembrane observed in glutathione-depleted preOLs are general featuresof apoptosis (Arends et al., 1990) reported to occur in oligodendrocytesin vitro (Cassaccia-Bonnefil et al., 1996) and in vivo (Li etal., 1996). These features differ from those seen in OLs undergoingnecrosis in vitro (Mitrovic et al., 1995). That a mitochondriallesion may be related to preOL death is suggested by the markedswelling of mitochondria in end-stage preOLs (Fig. 11D). Interestingly,mitochondrial swelling was an early event in thymocytes undergoingglucorticoid-induced apoptosis and occurred in association witha drop in mitochondrial membrane potential (Petit et al., 1995).Triggering of the permeability transition also caused matrix swellingthat resulted in release of multiple proteins from the mitochondrialintermembrane space, including cytochrome C (Scarlett and Murphy,1997). A decline in mitochondrial membrane potential (Zamzamiet al., 1996) associated with permeability transitions (Kristaland Dubinsky, 1997) and the release of cytochrome C (Rosse etal., 1998; Zhovotovsky et al., 1998) precede the downstream activationof caspases in apoptosis.

Our findings of maturation-dependent differences in OL viability in response to glutathione depletion are consistent withthe response of OLs to other sources of oxidative stress. C2-ceramidewas more toxic to O2A progenitors or CG-4 cells than to matureO1-positive OLs (Cassaccia-Bonnefil et al., 1996; Brogi et al.,1997), and the mechanism of ceramide-induced apoptosis appearsto involve an early rise in mitochondrial ROS generation (Quillet-Maryet al., 1997). OL precursors also generated higher levels of ROSthan astrocytes when made hypoxic or exposed to blue light, butmature OLs were not examined (Husain and Juurlink, 1995; Thorburneand Juurlink, 1996). Not all sources of oxidative stress to OLsinduced apoptosis, however. Although nitric oxide was toxic toOLs, the mechanism of death was necrotic (Mitrovic et al., 1995).Moreover, in immortalized OLs, nitric oxide had minimal toxicityto the least and most mature cell lines (Mackenzie-Graham et al.,1994).

One basis for the increased susceptibility of preOLs to oxidative stress may be a delayed maturational expression of genesthat suppress apoptosis, such as bcl-2 (Hockenbery et al., 1993;Rabizadeh et al., 1993) or p35 (Rabizadeh et al., 1993). Alternatively,the death of preOLs may be regulated by a specific pathway triggeredby oxidative stress that is downregulated in mature OLs. Recently,diminished expression of one member of the cysteine aspartasefamily of proteases, Nedd2, was shown to protect against trophicfactor withdrawal, whereas an interleukin-1 $beta$ -converting enzyme-likeprotease was activated when superoxide dismutase was downregulated(Troy et al., 1997). Thus, our in vitro system offers a well definedmodel to address the developmental regulation of genes that mayinfluence the maturational susceptibility of OLs to oxidativestress in the setting of perinatal white matter ischemia.

  FOOTNOTES

Received April 13, 1998; revised May 27, 1998; accepted June 8, 1998.

This research was supported by National Institutes of Health Grants NS01855 (S.A.B.) and P20NS32570 (P.A.R. and J.J.V.), NationalInstitute of Child Health and Human Development Grant P30HD18655(J.J.V.), a Grass Foundation Morison Fellowship (S.A.B.), a ReynoldsRich Smith Fellowship (S.A.B.), Charles A. Janeway Child HealthResearch Center Award Fellowship HD27805 (S.A.B.), and a HearstFoundation Award (S.A.B.). We thank Dr. David Zurakowski for adviceon the statistical analysis and Marcia Lind for excellent technicalassistance.
Correspondence should be addressed to Dr. Paul A. Rosenberg, Department of Neurology, Enders 3, Children's Hospital, 300 LongwoodAvenue, Boston, MA 02115.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Aizenman E (1995) Modulation of N-methyl-D-aspartate receptors by hydroxyl radicals in rat cortical neurons in vitro. Neurosci Lett 189:57-59[ISI][Medline].
Anderson ME, Levy EJ, Meister A (1994) Preparation and use of glutathione monoesters. In: Oxygen radicals in biological systems, Vol 234, Part D (Packer L, ed), pp 492-499. San Diego: Academic.
Arends M, Morris R, Wyllie A (1990) Apoptosis: the role of the endonuclease. Am J Pathol 136:593-608[Abstract].
Back SA, Volpe JJ (1997) Cellular and molecular pathogenesis of periventricular white matter injury. MRDD Research Reviews 3:96-107.
Back SA, Yonezawa M, Gan X, Rosenberg PA, Volpe JJ (1995) Oligodendrocyte death induced by cystine deprivation occurs by apoptosis. Soc Neurosci Abstr 21:41.
Back SA, Volpe JJ, Kinney HH (1996) Immunocytochemical characterization of oligodendrocyte development in human cerebral white matter. Soc Neurosci Abstr 20:1722.
Bansal R, Warrington A, Gard A, Ranscht B, Pfeiffer S (1989) Multiple and novel specificities of monoclonal antibodies O1, O4, and R-mAb used in the analysis of oligodendrocyte development. J Neurosci Res 24:548-557[ISI][Medline].
Barres BA, Raff MC (1994) Control of oligodendrocyte number in the developing rat optic nerve. Neuron 12:935-942[ISI][Medline].
Bogler O, Wren D, Barnett SC, Land H, Noble M (1990) Cooperation between two growth factors promotes extended self-renewal and inhibits differentiation of oligodendrocyte-type-2 astrocyte (O-2A) progenitor cells. Proc Natl Acad Sci USA 87:6368-6372[Abstract/Free Full Text].
Bojes H, Datta K, Xu J, Chin A, Simonian P, Nunez G, Kehrer J (1997) Bcl-x_L overexpression attenuates glutathione depletion in FL5.12 cells following interleukin-3 withdrawal. Biochem J 325:315-319.
Bolanos J, Heales S, Peuchen S, Barker J, Land J, Clark J (1996) Nitric oxide-mediated mitochondrial damage: a potential neuroprotective role for glutathione. Free Radic Biol Med 21:995-1001[ISI][Medline].
Brogi A, Strazza M, Melli M, Costantino-Ceccarini E (1997) Induction of intracellular ceramide by interleukin-1 $beta$ in oligodendrocytes. J Cell Biochem 66:532-541[ISI][Medline].
Cassaccia-Bonnefil P, Aibel L, Chao M (1996) Central glial and neuronal populations display differential sensitivity to ceramide-dependent cell death. J Neurosci Res 43:382-389[ISI][Medline].
Chernyak B, Bernardi P (1996) The mitochondrial permeability transition pore is modulated by oxidative agents through both pyridine nucleotides and glutathione at two separate sites. Eur J Biochem 238:623-630[ISI][Medline].
Dugan L, Sensi S, Canzoniero L, Handran S, Rothman S, Lin T-S, Goldberg M, Choi D (1995) Mitochondrial production of reactive oxygen species in cortical neurons following exposure to N-methyl-D-aspartate. J Neurosci 15:6377-6388[Abstract/Free Full Text].
Ellerby L, Ellerby H, Park S, Holleran A, Murphy A, Fiskum G, Kane D, Testa M, Kayalar C, Bresden D (1996) Shift of the cellular oxidation-reduction potential in neural cells expressing Bcl-2. J Neurochem 67:1259-1267[ISI][Medline].
Flodmark O, Lupton B, Li D (1989) MR imaging of periventricular leukomalacia in childhood. AJNR 10:111-118.
Gard AL, Pfeiffer SE, Williams III WC (1993) Immunopanning and developmental stage-specific primary culture of oligodendrocyte progenitors (O4+GalC-) directly from postnatal rodent cerebrum. Neuroprotocols 2:209-218.
Griffith OW (1982) Mechanisms of action, metabolism and toxicity of buthionine sulfoximine and its higher homologs, potent inhibitors of glutathione synthesis. J Biol Chem 257:13704-13712[Free Full Text].
Griffith OW, Meiste