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1From the Departments of Pharmacology and Neuroscience and 3Pathology and Anatomy, the 5Division of Cell Biology and Genetics, and the 6North Texas Eye Research Institute, University of North Texas Health Science Center, Fort Worth, Texas; the 2Department of Pharmacodynamics, College of Pharmacy, University of Florida, Gainesville, Florida; and 4MitoKor, San Diego, California.
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Abstract |
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METHODS. To investigate the involvement of 17ß-estradiol (17ß-E2) in protection against oxidative stress, HLECs were exposed to insult with H2O2 at a physiological level (100 µM) over a time course of several hours, with and without pretreatment with 17ß-E2. Cell viability was measured by calcein AM assay, and 2',7'-dichlorofluorescein diacetate (DCFH-DA) was used to determine intracellular reactive oxygen species (ROS). Intracellular adenosine triphosphate (ATP) level was quantified with a luciferin- and luciferase-based assay and mitochondrial potential (
m) was monitored by a fluorescence resonance energy-transfer technique.
RESULTS. H2O2 caused a dose-dependent decrease in mitochondrial membrane potential, intracellular ATP levels, and cell viability. Dose-dependent increases in cell viability and intracellular ATP level were observed with pretreatment of 17ß-E2 for 2 hours before oxidative insult. At 1 nM, 17ß-E2 increased cell viability from 39% ± 4% to 75% ± 3%, and at 100 nM or higher, it increased survival to greater than 95%. The level of intracellular ATP approached normal with 17ß-E2 at 100 nM or higher. Pretreatment with 17ß-E2 did not diminish intracellular ROS accumulation after exposure to H2O2. Moreover, two nonfeminizing estrogens, 17
-E2 and ent-E2, both of which do not bind to either estrogen receptor or ß, were as effective as 17ß-E2 in the recovery of cell viability. The estrogen receptor antagonist, ICI 182,780, did not block protection by 17ß-E2. Both 17ß- and 17-E2 moderated the collapse of m in response to either H2O2 or excessive Ca2+ loading.
CONCLUSIONS. The present study indicates that both 17- and 17ß-E2 can preserve mitochondrial function, cell viability, and ATP levels in human lens cells during oxidative stress. Although the precise mechanism responsible for protection by the estradiols against oxidative stress remains to be determined, the ability of nonfeminizing estrogens, which do not bind to estrogen receptors, to protect against H2O2 toxicity indicates that this conservation is not likely to be mediated through classic estrogen receptors.
There is a higher incidence of cataract in postmenopausal women than in age-matched men, which leads to the notion that the absence of estrogens may contribute to the increased risk.2 3 4 5 6 Indeed, epidemiologic studies indicate beneficial effects of hormone replacement therapy (HRT) against cataract in postmenopausal women.7 8 9 10 11 12 For example, the Beaver Dam Eye Study10 and the Salisbury Eye Evaluation Project7 have both found protective associations between hormone use and lens nuclear opacity. In addition, another large cross-sectional study, the Blue Mountains Eye Study,8 found that HRT was associated with reduced cortical opacity in lens. Recent epidemiologic reevaluation of the Blue Mountains Eye Study determined a significant trend for increasing incidence of nuclear cataract in postmenopausal women.11 Weintraub et al.,12 recently evaluated HRT and lens opacities in a population of 480 postmenopausal women and determined that "current use of estrogen-only preparations was associated with a 49% decreased risk of nuclear opacities compared with never use." Studies using tissue culture and animal models also suggest beneficial effects of estrogen in lens. In a lens culture system, estrogen protected lenses against cataracts induced by transforming growth factor (TGF)-ß.13 Estrogen has also been reported to exert protective effects in a rat model of age-related cataracts induced by methylnitrosourea (MNU).14
Several studies have demonstrated the beneficial effects of the antioxidant activity of estrogen and, further, that the hormone’s action is independent of classic receptor-dependent mechanisms. Our laboratory has shown that estradiol at physiological concentrations can block membrane oxidation.15 Estrogen treatment has been shown to reduce lipid peroxidation induced by glutamate and further to attenuate the acceleration of intracellular peroxide production resulting from exposure to H2O216 and by mitochondrial electron transport inhibitors.17 Consistent with these data are studies showing that estrogen inhibits formation of lipid peroxyls and oxidation of low-density lipoproteins in vitro.18 19 In vivo studies have demonstrated that estrogen replacement therapy provided by transdermal patch reduces low-density lipoproteins.20 These effects of estrogen do not appear to require estrogen receptors (ERs),21 22 23 suggesting that estrogen exerts antioxidant activities through ER-independent mechanisms.
In the current study, we tested, for the first time, the protective effects of estrogens against oxidative stress using in vitro cultured human lens epithelial cells (HLECs). Elevated levels of H2O2 are found in the lenses and aqueous humor of patients with cataract,24 25 26 and it is held that H2O2 is a major oxidant that contributes to formation of cataract.27 In the present study, we assessed the ability of 17ß-estradiol (17ß-E2) to protect against the adverse effects of H2O2 on mitochondrial membrane potential (m), intracellular adenosine triphosphate (ATP) levels, and cell viability in HLECs. Further, we attempted to assess the role of estrogen receptors (ERs) in this action of estrogens on lens viability by using two nonfeminizing estrogens that do not bind to ERs, 17-estradiol (17-E2) and Ent-estradiol (ent-E2), and an ER antagonist, ICI 182,780.
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Material and Methods |
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-E2 were purchased from Steraloids, Inc. (Wilton, NH). ICI 182,780 was purchased from Tocris (Ellisville, MO). The complete enantiomer of 17ß-E2, Ent-E2, was synthesized by methods that we have previously described.28 All steroids and ICI 182,780 were dissolved in ethanol at a final concentration of 10 mM and diluted to appropriate concentration in culture medium as required. Unless otherwise stated, steroid treatment to cell cultures involved a 2-hour preincubation followed by continued administration of the steroid in the presence of H2O2. Those cells receiving vehicle (in place of estradiol) pretreatment were maintained in fresh culture medium at the same final ethanol concentration. Control cells were maintained in culture medium with appropriate changes of fresh medium. In experiments involving the ER antagonist ICI 182,780, it was added 30 minutes before addition of 17ß-E2.
H2O2 was purchased from Mallinckrodt Baker Inc. (Paris, KY). H2O2 was diluted with culture medium to final concentration before using. Calcein AM, 2,7-dichlorofluorescin diacetate (DCFH-DA), and ATP determination kits were purchased from Molecular Probes (Eugene, OR).
Cell Culture
HLE-B3 cells, a human epithelial cell line immortalized by simian virus (SV)-40 viral transformation,29 were obtained from Usha Andley (Washington University School of Medicine, Department of Ophthalmology, St. Louis, MO) and cultured in Eagle’s minimal essential medium (MEM) supplemented with 20% fetal bovine serum (Hyclone Laboratories, Logan, UT) and 20 µg/mL gentamicin (Sigma, St. Louis, MO) in 150-cm2 culture flasks at 37°C and 5% CO2 and 95% air. All experiments were performed with HLE-B3 cells between passages 18 and 25.
Measurement of Reactive Oxygen Species
The extent of cellular oxidative stress was estimated by monitoring the generation of reactive oxygen species (ROS) using the fluorescent dye DCFH-DA. Cells were plated 24 hours before initiation of the experiment at a density of 5000 cells per well in 96-well plates. Cells were loaded with DCFH-DA at a final concentration of 50 µM for 45 minutes. After incubation, DCFH-DA was removed, and cells were washed twice with 1x PBS (pH 7.4) and incubated with MEM containing 20% FBS with a bolus dose of H2O2 (50 and 100 µM) for 10 to 60 minutes, DCFH-DA fluorescence was determined at an excitation of 485 nm and an emission of 538 nm, by microplate-reader (model FL600; Biotek, Highland Park, VT). Values were normalized to the percentage in untreated control groups. It should be noted that, "DCFH-DA is taken up by cells and tissues, usually undergoing deacetylation by esterase enzymes. Oxidation of DCFH within cells leads to fluorescent dichlorofluorescein, which can easily be visualized (strong emission at 525 nm with excitation at 488 nm). This technique is becoming popular as a means of visualizing ‘oxidative stress’ in living cells. In addition to peroxidase/H2O2, several species cause DCFH oxidation, probably including RO2·, RO·,OH·, HOCl, and ONOO-, but not O2·-or H2O2. Hence, this ‘fluorescent imaging’ is an assay of generalized ‘oxidative stress’ rather than of production of any particular oxidizing species, and it is not a direct measure of H2O2."30
Calcein AM Assay
Cells were plated 24 hours before the initiation of the experiment, at a density of 5000 cells per well in 96-well plates. Cells were exposed to two doses of H2O2 (50 and 100 µM) from 1 to 24 hours. After exposure to H2O2, cells were rinsed with 1x PBS (pH 7.4), and viability was assessed by the addition of 25 µM calcein AM, as previously described.28 Calcein AM fluorescence was determined at an excitation of 485 nm and an emission of 538 nm with the microplate reader (FL600; Biotek). Percentage viability was calculated by normalization of all values to the H2O2-free control group (100%). Calcein staining was visualized by fluorescence microscope (Diaphot-300; Nikon, Tokyo, Japan), and cells were photographed for qualitative documentation. Four random fields of cells were examined, and photographs were taken of cells in 96-well plates.
Measurement of ATP Levels
Cells were plated at a density of 5 x 105 cells per well in 12-well plates. After 48 hours, cells were exposed to various doses of H2O2 from 15 minutes to 8 hours. Cellular ATP levels were quantified with a luciferin and luciferase-based assay.31 Cells were washed with PBS once and lysed with ATP-releasing buffer (100 mM potassium phosphate buffer [pH 7.8]: 1% Triton X-100, 2 mM EDTA, and 1 mM dithiothreitol [DTT]). Ten microliters of the lysate was added to 96-well plates (InterMed, Naperville, IL) . ATP concentrations in lysate were quantified using an ATP-determination kit according to the manufacturer’s instruction. The 96-well plates were then read (SpectraMAX GeminiXS plate reader; Molecular Devices, Sunnyvale, CA). A standard curve was generated with solutions of known ATP concentrations. Protein concentration of samples were determined by Bradford assay.32 ATP levels were calculated as nanomolar ATP per milligram protein and normalized to levels in untreated control cultures.
Monitoring m
m was recorded in intact and digitonin-permeabilized cells with an assay based on fluorescence resonance energy transfer (FRET) between two dyes: nonyl acridine orange (NAO; Molecular Probes), which stains cardiolipin, lipid found exclusively in the mitochondrial inner membrane, and tetramethylrhodamine (TMRE; Molecular Probes), a potentiometric dye taken up by mitochondria in accord with Nernstian dictates potential and concentration. The presence of TMRE quenches NAO emission in proportion to m, whereas loss of m with consequent efflux of TMRE dequenches NAO.33 34 The high specificity of NAO staining; selective monitoring of the fluorescence emitted by NAO, not TMRE; and the stringent requirement for colocalization of both dyes within the mitochondrion, all act in concert to allow the FRET assay to report m, unconfounded by background signal arising from potentiometric dye responding to plasma membrane potential.
Twenty-four hours before assay, cells were trypsinized and plated in clear-bottomed, black-walled, 96-well plates (Costar 3606; Corning International, Corning, NY). Cells were plated at 60,000 per well for use in high-throughput screening protocols, as described previously.16 28
Statistical Analyses
Effects on m were quantified by calculating the area under the curve (AUC) after either Ca2+ challenge or addition of H2O2. To partially correct for variations in cell density, staining and optical aberrations in these plates, all wells were normalized to the initial relative fluorescence units (RFU) reading in each well using a fluorescence-imaging plate reader (FLIPR; with accompanying software; Molecular Devices). In a variation of the analysis, the AUC was divided by the amount of initial quenching of NAO, which is an alternate technique to compensate for variability in cell density and staining and for optical aberrations. Dose–response data were fitted on computer by nonlinear regression analysis (sigmoid equations; Prism, ver. 3.00 for Windows; GraphPad Software, San Diego, CA). One way ANOVA and Bonferroni post hoc testing were performed with the same software.
The significance of differences among groups was determined by one-way ANOVA. Planned comparisons between groups were determined by the Tukey test. For all tests, P < 0.05 was considered significant.
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Results |
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Cell Viability.
H2O2 induced a time- and dose-dependent decline in cell viability (Fig. 1c) . At 50 µM, it decreased cell viability to 65% ± 2% of control by 12 hours after exposure. Exposure to 100 µM H2O2 had a significantly greater effect on viability of HLECs, with the surviving of cells declining to 45% ± 4% by 2 hours and almost complete cell death by 8 hours after H2O2 treatment.
Effects of 17ß-E2 against H2O2 Exposure on HLECs
Because 100 µM H2O2 had a significant impact on ROS accumulation, intracellular ATP content, and cell viability, this concentration was selected for further studies with estrogens.
H2O2-Induced ROS Increase in HLECs.
As in Figure 1a , 100 µM H2O2 progressively and significantly increased intracellular ROS over the 60-minute observation period. Concentrations of 17ß-E2 ranging from 1 nM to 10 µM did not modify intracellular accumulation of ROS (Fig. 2) .
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- and 17ß-E2 on Ca2+- and H2O2-Mediated Collapse of mm in intact HLECs (Fig. 5) . Even a brief 5-minute incubation with either 17- or 17ß-E2 at 0.5 µM substantially reduced the magnitude of this ionomycin-induced m collapse (Fig. 5) , reflected by an increase in EC50 from 0.95 µM to 1.6 and 2.3 µM for 17- and 17ß-E2, respectively. Thus, it required more Ca2+ to induce comparable m collapse when the estradiols were present, or conversely, under comparable Ca2+ loading, a larger portion of the mitochondrial population retained its membrane potential in the presence of estradiols. Note also that the magnitude of the m collapse in the presence of 17ß-E2, expressed as total AUC, was lower than with buffer and 17-E2, even at the highest ionomycin concentrations (Fig. 5) .
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m acutely (response within seconds) was substantially more than the concentration necessary in the long-term cytotoxicity studies. In any event, the magnitude of m collapse induced by H2O2 was moderated by both 17ß- and 17-E2 at 0.5 µM (preincubation for 30 minutes), although this occurred predominantly at higher H2O2 concentrations (0.1 and 1 mM). For example, EC50 was not significantly different between control and estradiol treatments, but one-way ANOVA of the total AUC during the response reveals significant moderation of m collapse by both 17ß- and 17-E2 (F = 3.9, P < 0.03).
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-E2, and then challenged with a Ca2+ load through application of ionomycin described earlier. 17ß- or 17-E2 moderated m collapse, repressing the magnitude of the response more than its rate (Figs. 7 8) . In all three replicates, the estradiols consistently increase the EC50 for ionomycin (Fig. 8 ; Table 1 ). To control for potential effects of the compounds on cell growth or loss during the prolonged (6-hour) preincubation, the AUC data from each well were normalized to the cell density in that well at the start of the observations by dividing the AUC by the magnitude of quenching of the initial fluorescence signal by the potentiometric dye (A, initial signal; B, signal after quenching). Thus, AUC/(A - B) provides an index of compound efficiency that is independent of effects on cell viability.34
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-E2) or no (Ent-E2) binding capacity to ERs were examined. Compared with the potent natural estrogen 17ß-E2, 17-E2 binds weakly to ERs, and the 17-E2–ER complex only transiently binds to the estrogen-responsive element.28 35 36 37 Ent-17ß-E2, the enantiomer of 17ß-E2, has identical physiochemical properties as 17ß-E2, with the crucial exception that it is incapable of interacting with other stereospecific molecules, such as the ERs.28 At 100 nM, 17ß-E2 improved cell survival from 32% ± 3% to 76% ± 3%. Both 17-E2 and Ent-E2 displayed equivalent effectiveness against H2O2-induced cytotoxicity. 17-E2 increased cell survival to 73% ± 3% and Ent-E2 enhanced cell viability to 79% ± 4% (Fig. 9) , suggesting that the protective action of 17ß-E2 is not mediated by classic ERs.
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Discussion |
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m, and profound depletion of ATP and that estrogens potently protected against collapse of m, ATP depletion, and cell death without affecting production of ROS such as H2O2, RO2·, RO·, OH·, HOCl, and ONOO-. Collectively, these data suggest that the reported protection from cataracts afforded by HRT in postmenopausal women7 8 9 10 11 12 is due to these cytoprotective effects against H2O2 toxicities in lens epithelial cells. H2O2 is a potent diffusible pro-oxidant that initiates a series of oxidative events in cells.38 39 We observed that HLECs adaptively responded to a low concentration (50 µM) of H2O2, as evidenced by a modest increase in ROS, maintenance of stable, albeit lower, concentrations of ATP, and relative resistance to cell death. In contrast, the higher (100 µM) concentration of H2O2 was associated with a delayed but profound increase in ROS, a rapid and marked decline in ATP concentrations, and nearly complete cell death within 8 to 12 hours. This higher concentration of H2O2 is clearly a pathologic insult, from which cells failed to recover under the conditions of this study.
Our first assessment of the effects of 17ß-E2 was on production of ROS, using an indicator that detected soluble ROSs. In this assay, 17ß-E2 at concentrations ranging from low physiological (1 nM) to pharmacologic (10 µM) were ineffective in changing the ROS response to H2O2. Clearly, the cytoprotective effects of 17ß-E2 in this cell line are not dependent on its ability to affect the production or clearance of soluble ROS. A possibility that we have not explored in the present study is that estrogens may affect lipid peroxidation, without affecting soluble ROS. Estrogens are lipid soluble and preferentially penetrate in cellular membranes.40 In neuronal cultures, physiological concentrations of 17ß-E2 effectively reduce lipid peroxidation.22 41 However, it is clear from our data that in HLECs, soluble ROS are not influenced by exposure to estrogen.
The ATP depletion induced by H2O2 treatment no doubt reflects at least two actions of the pro-oxidant: interruption of oxidative production of ATP with the concomitant depletion of the energy-containing molecule as a result of attempts to repair damage caused by H2O2. Either or both mechanisms may be involved in the depletion of ATP, although we have observed that H2O2 causes a profound downregulation in several oxidative phosphorylation enzyme transcripts (Cammarata PR, Moor AN, unpublished observations, 2002), an effect that would certainly help undermine ATP production. Moreover, we do not exclude the well-known dramatic inactivation of glyceraldehyde-3-phosphate dehydrogenase by H2O2 as part of the explanation for the decline in intracellular ATP.42 Whether estradiol prevents the inactivation of glyceraldehyde-3-phosphate dehydrogenase by peroxide, thereby contributing to the restoration of intracellular ATP, is currently under investigation.
On shorter time scales, it is well known that oxidative insult readily represses electron transport efficiency and oxidative phosphorylation, primarily by inactivating both the Fe-S reaction centers of several of the electron transport respiratory centers, and heme moieties in the cytochromes.39 43 In addition, even without the downregulation of mitochondrial gene expression noted earlier, the data show that H2O2 directly collapses m in HLECs, an event that not only eliminates the driving force for mitochondrial ATP production, but that also exacerbates subsequent free radical production.39 43
Damage to mitochondria can lead to deficiency in ATP production and to a concomitant increase in production of ROS that can overwhelm cellular antioxidant defense systems. Under conditions of oxidative stress, mitochondria undergo a catastrophic, irreversible loss of the impermeability of the inner mitochondrial membrane that causes a complete collapse of m, a process called permeability transition (PT).44 Accelerated mitochondrial radical production compromises cellular and mitochondrial integrity by inducing peroxidation of membrane lipids and impeding oxidative phosphorylation. The resultant acute loss of ATP causes the transmembrane ion-dependent ATPases to fail, thereby precipitating cell death from osmotic failure.39 45
17ß-E2 was effective in protecting cellular ATP levels and in protecting HLECs from death. A dose-dependent increase in cellular ATP levels was observed from 100 nM to 10 µM. These data suggest that at pharmacologic concentrations of estrogens, cellular ATP is preserved. Inasmuch as ATP is essential for normal cellular function, including its survival, this action of 17ß-E2 may be necessary, but insufficient for the observed cytoprotective effects. Indeed, it appears that the cytoprotective effects of 17ß-E2 occur at concentrations lower than those needed for ATP maintenance. As such, other actions of 17ß-E2 are involved in its cytoprotective effects. Although we do not know the precise mechanism of the cytoprotective effects of estrogens in HLECs, in neurons a plethora of cellular responses to the steroid have been reported, including the protection of mitochondrial function, stimulation of antiapoptotic proteins, and stimulation of protective signaling pathways.46 47 48 49 50 51
The data in the current study indicate that both 17- and ß-E2 equipotently increased the amount of Ca2+ or H2O2 necessary to collapse m in HLECs, effectively stabilizing mitochondrial integrity and preserving function under pathogenic conditions. This effect does not require prolonged exposure to the estradiols—it became apparent in 5- and 30-minute incubations—yet it was also apparent after a 6-hour preincubation. The result is that, at a given Ca2+ or oxidative load, a larger portion of the mitochondrial population retains m and hence continues to function. Such a response readily explains preservation of ATP levels by estradiols during exposure to H2O2, as well as repression of cell death through both necrosis and apoptosis under these conditions.
The mitoprotective effects of the estradiols shown in the m assay could be due to any combination of the mechanisms of action known for this class of compounds46 47 48 49 50 51 such as membrane stabilization,40 which is particularly germane to the retention of m. Indeed, the moderation by estrogens of m collapse could be due to a repression of Ca2+ uptake into the mitochondria through the uniporter, to increased Ca2+ efflux from the mitochondria, or to a direct membrane-stabilization effect, all of which would yield similar-appearing responses in this assay. In addition, although both 17- and ß-E2 equipotently repressed the magnitude of m collapse induced by either Ca2+ or H2O2 in the FRET assay (Figs. 5 6 7 8) , the data do not permit distinguishing a modest effect in most of the mitochondrial population from a profound effect in a smaller mitochondrial subpopulation. It is apparent, however, that in the absence of additional stressors, the estrogens alone do not dissipate or hyperpolarize m, as is reflected by comparable amounts of initial quenching, seen as coincidence of the curves between 100 and 300 seconds before the addition of ionomycin (Fig. 7) . At the very least, this suggests that the estrogens do not exert their protective effects by uncoupling electron transport, a mechanism known to protect neuronal cells from oxidative stress and Ca2+ loading associated with glutamate excitotoxicity.52
Our results argue against a primary involvement of ERs in the observed effects of estrogens. However, we have, in fact, confirmed the positive presence of ER- and -ß in the cultured HLEC strain HLE-B3 by RT-PCR analysis and subsequent verification of the PCR products by sequence analysis and Southern blot with specific internal oligonucleotides to the directed primer pairs, as well as by immunofluorescence techniques (manuscript in preparation). Three estrogens, 17ß-, 17-, and Ent-E2, that differ by as much as 32-fold in their affinity for either ER- or -ß,28 35 36 37 have equivalent effects on HLEC survival and the action of 17ß-E2 was not antagonized by the prototypic ER antagonist ICI 182,780. The ICI compound itself exerted cytoprotective activity, probably the result of its phenolic A ring, a requirement for cytoprotection by estrogens.21 23 45 In this respect, a recent study by Han et al.,53 demonstrated that the protective potency of various estrogens was dependent on the precise estrogenic structure. Whereas 17-E2, a phenolic ring estrogen, acted similar to the antioxidants taurine and vitamin C against the peroxide-induced damage to cultured rabbit renal proximal tubule cells, 17ß-E2, a catecholic estrogen, behaved in a manner similar to the iron chelators deferoxamine and phenanthroline. In this regard, it is important to further point out that superoxide dismutase mimics, in particular, TEMPOL (Sigma),54 prevents Fe+2–mediated generation of the damaging hydroxyl radical, by reacting with superoxide, thus preventing recycling of Fe+3 to Fe+2, while deferoxamine chelates intracellular Fe+3 and prevents its reduction to Fe+2. We cannot at this time rule out the possibility that 17ß-E2, like the superoxide dismutase (SOD) mimic TEMPOL or deferoxamine, acts by limiting the availability of Fe+2 and thereby prevents certain damaging effects of H2O2. Irrespective of the precise mode of action of 17ß-E2, the study by Han et al.,53 raises the interesting possibility that various estrogens have differential cytoprotective potential, and by inference, disparity in their mechanisms of action. Of immediate relevance to our studies, however, Han et al., like us, conclude that "these cytoprotective effects of estrogens are not dependent on classical estrogen receptors."53
In contrast, a recent study by Davis et al.,55 argues that estrogen protection in the eye may result from direct interactions with its ocular ERs. Studies in their transgenic mouse model, which express ER-, a dominant-negative form of ER- that inhibits ER- function, show spontaneous cortical cataracts that progress with age in transgene-positive women after puberty.
Collectively, our studies demonstrate that estrogens are potent cytoprotectants that preserve mitochondrial function during oxidant insult in HLECs in culture. These results indicate that estrogens may be useful therapies for the prevention of cataracts in postmenopausal women and that nonfeminizing estrogens could provide similar protection in men.
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Disclosure: X. Wang, None; J.W. Simpkins, None; J.A. Dykens, MitoKor (E); P.R. Cammarata, None
The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 
1734 solely to indicate this fact.
Corresponding author: Patrick R. Cammarata, Department of Pathology and Anatomy, Division of Cell Biology and Genetics, University of North Texas Health Science Center, 3500 Camp Bowie Boulevard, Fort Worth, TX 76107; pcammara{at}hsc.unt.edu.
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) and 17
) on the collapse of 
), as reflected by the EC50 of 2.31 and 1.55 µM for 17ß-E2 and 17
