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Volume 17, Number 13,
Issue of July 1, 1997
pp. 5089-5100
Copyright ©1997 Society for Neuroscience
Evidence that 4-Hydroxynonenal Mediates Oxidative Stress-Induced
Neuronal Apoptosis
Inna Kruman1,
Annadora
J. Bruce-Keller1,
Dale Bredesen2,
Georg Waeg3, and
Mark P. Mattson1
1 Sanders-Brown Research Center on Aging and Department
of Anatomy and Neurobiology, University of Kentucky, Lexington,
Kentucky 40536, 2 Program on Aging, The Burnaham Institute,
La Jolla Cancer Research Foundation, La Jolla, California 92037, and
3 Institute for Biochemistry, University of Graz, A-8010
Graz, Austria
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Oxidative stress is believed to play important roles in neuronal
cell death associated with many different neurodegenerative conditions
(e.g., Alzheimer's disease, Parkinson's disease, and cerebral
ischemia), and it is believed also that apoptosis is an important mode
of cell death in these disorders. Membrane lipid peroxidation has been
documented in the brain regions affected in these disorders as well as
in cell culture and in vivo models. We now provide
evidence that 4-hydroxynonenal (HNE), an aldehydic product of membrane
lipid peroxidation, is a key mediator of neuronal apoptosis induced by
oxidative stress. HNE induced apoptosis in PC12 cells and primary rat
hippocampal neurons. Oxidative insults (FeSO4 and amyloid
 -peptide) induced lipid peroxidation, cellular accumulation of HNE,
and apoptosis. Bcl-2 prevented apoptosis of PC12 cells induced by
oxidative stress and HNE. Antioxidants that suppress lipid peroxidation
protected against apoptosis induced by oxidative insults, but not that
induced by HNE. Glutathione, which binds HNE, protected neurons against
apoptosis induced by oxidative stress and HNE. PC12 cells expressing
Bcl-2 exhibited higher levels of glutathione and lower levels of HNE
after oxidative stress. Collectively, the data identify that HNE is a
novel nonprotein mediator of oxidative stress-induced neuronal
apoptosis and suggest that the antiapoptotic action of glutathione may
involve detoxification of HNE.
Key words:
Alzheimer's disease;
amyloid -peptide;
Bcl-2;
glutathione;
hippocampal neurons;
iron;
lipid peroxidation;
mitochondria;
programmed cell death;
reactive oxygen species;
vitamin
E
INTRODUCTION
Oxidative stress may contribute to neuronal
dysfunction and death in an array of disorders, including stroke,
Alzheimer's disease (AD), and Parkinson's disease (for review, see
Jesberger and Richardson, 1991 ; Mattson et al., 1996; Simonian and
Coyle, 1996). Reactive oxygen species (ROS) are generated in several metabolic pathways, a major source being mitochondrially derived superoxide anion radical, which gives rise to hydrogen peroxide, which
is converted further to hydroxyl radical, which induces membrane lipid
peroxidation (Evans, 1993). Systems that detoxify ROS include the
enzymes superoxide dismutase, catalase, and glutathione peroxidase and
the thiol tripeptide glutathione (GSH). Oxidative stress occurs in
neurons exposed to excitotoxins (Lafon-Cazal et al., 1993; Dugan et
al., 1995; Mattson et al., 1995a), metabolic poisons (Beal et al.,
1995), ischemia (Chan, 1996), and amyloid -peptide (A) (Behl et
al., 1994; Goodman and Mattson, 1994). By damaging ion transport
proteins and other regulatory systems in membranes, lipid peroxidation
may be particularly detrimental to neurons (Mark et al., 1995,
1997).
Apoptotic cell death is characterized by cell shrinkage, cell surface
blebbing, chromatin condensation, and DNA fragmentation with
maintenance of membrane and organellar integrity; macromolecular synthesis inhibitors can prevent apoptosis, suggesting an active or
"programmed" mechanism of cell death (for review, see Bredesen, 1995; Johnson et al., 1995; Steller, 1995; Thompson, 1995). Necrosis is
another form of cell death in which cells swell, mitochondria and other
organelles are damaged, and the plasma membrane ruptures. Neuronal
apoptosis may occur in stroke (Linnik et al., 1993; MacManus et al.,
1993; Nitatori et al., 1995), AD (Loo et al., 1993; Su et al., 1994;
Anderson et al., 1995), and Huntington's disease (Portera-Cailliau et
al., 1995). The involvement of ROS in apoptosis is suggested by studies
showing that apoptotic stimuli induce accumulation of ROS in neurons
and that antioxidants can prevent apoptosis (Kane et al., 1993;
Whittemore et al., 1994; Ferrari et al., 1995; Greenlund et al., 1995;
Mark et al., 1995).
Proapoptotic gene products such as interleukin-1-converting
enzyme (ICE) (Troy et al., 1996a) and antiapoptotic gene products such
as Bcl-2 (Hockenbery et al., 1993; Kane et al., 1993; Mah et al., 1993;
Reed, 1994; Wiedau-Pazos et al., 1996) may play roles in oxidative
stress-induced apoptosis. On the other hand, nonprotein mediators of
apoptosis have not been identified. 4-Hydroxynonenal (HNE), an
aldehydic product of lipid peroxidation, is cytotoxic to non-neuronal
cells at concentrations reached when cells are exposed to various
oxidative insults (Esterbauer et al., 1991). HNE forms covalent
cross-links with proteins via Michael addition to lysine, cysteine, and
histidine residues (Uchida and Stadtman, 1993; Uchida et al., 1994);
HNE normally is detoxified by conjugation with GSH (Spitz et al., 1990;
Grune et al., 1994; Ullrich et al., 1994). It is not known whether HNE
induces apoptosis nor whether HNE is involved mechanistically in
oxidative stress-induced apoptosis. We now report that HNE is generated
in response to apoptotic oxidative insults and can induce neuronal
apoptosis at pathophysiologically relevant concentrations.
MATERIALS AND METHODS
Materials. HNE, propanal, pentanal, heptanal, and
nonenal were purchased from Cayman Chemical (Ann Arbor, MI).
3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT),
hexanal, malondialdehyde, vitamin E ( -tocopherol), propyl gallate,
glutathione (GSH)-ethyl ester, cycloheximide, actinomycin-D, ATA, and
buthionine sulfoximine (BSO) were obtained from Sigma (St. Louis, MO).
Nonaldehyde was from Aldrich (Milwaukee, WI), and
trans-2-nonenal was from Wako Pure Chemicals (Osaka, Japan).
Aldehydes were prepared as 200-500× stocks in ethanol; ethanol
vehicle (0.2-0.5% final concentration) was added to control cultures.
A25-35 was purchased from Bachem (Torrence, CA) and dissolved in
water at a concentration of 2 mM 2-4 hr before
experiments. Hoescht 33342, propidium iodide, rhodamine 123, and
monochlorobimane were obtained from Molecular Probes (Eugene, OR). The
antibody against HNE-conjugated proteins was generated and
characterized as described in our previous study (Waeg et al., 1996).
FITC-Annexin-V was obtained from Nexins Research.
PC12 and rat hippocampal cell cultures and experimental
treatments. Control vector-transfected PC12 cells (PC12-V) and
PC12 cells expressing high levels of human Bcl-2 (PC12-Bcl2) were
established by methods described in our previous studies (Kane et al.,
1993; Zhong et al., 1993a). Cultures were maintained at
37°C (5% CO2 atmosphere) in RPMI-1640 medium
supplemented 10% with heat-inactivated horse serum and 5% with
heat-inactivated fetal bovine serum; immediately before experimental
treatment the medium was replaced with RPMI-1640 containing 1% fetal
calf serum. Rat hippocampal cell cultures were established from 18 d embryos, as described previously (Mattson et al., 1995b); experiments
were performed in cells that had been in culture for 6-8 d.
Immediately before experimental treatment the culture medium was
replaced with Locke's solution containing (in mM): NaCl
154, KCl 5.6, CaCl2 2.3, MgCl2 1.0, NaHCO3 3.6, glucose 5, and HEPES 5, pH 7.2.
Analyses of necrosis and apoptosis. Numbers of trypan
blue-positive (necrotic) and -negative cells were counted in four 20× fields per culture (typically 70-100 cells/20× field), and the percentage of trypan blue-positive cells in each culture was
calculated. Under control conditions <5% of the cells were trypan
blue-positive. Methods used to establish apoptotic cell death included
Hoescht and propidium iodide staining of DNA, annexin-V binding, and
suppression of cell death by macromolecular synthesis inhibitors. For
Hoescht and propidium iodide staining, cells were fixed in 4%
paraformaldehyde, membranes were permeabilized with 0.2% Triton X-100,
and cells were stained with the fluorescent DNA-binding dyes Hoescht
33342 or propidium iodide, as described previously (Mark et al., 1995). Hoescht-stained cells were visualized and photographed under
epifluorescence illumination (340 nm excitation and 510 nm barrier
filter) with a 40× oil immersion objective (200 cells per culture were
counted, and counts were made in at least four separate cultures per
treatment condition; analyses were performed without knowledge of the
treatment history of the cultures). The percentage of apoptotic cells
(cells with condensed and fragmented DNA) in each culture was
determined. Images of propidium iodide-stained cells were acquired with
a confocal laser scanning microscope (488 nm excitation and 510 nm
barrier filter; Molecular Dynamics, Sunnyvale, CA ) with a 60× oil
immersion objective. Alterations in plasma membrane phospholipids linked to apoptosis were detected by fluorescently labeled annexin-V, as described previously (Vermes et al., 1995; Van Engeland et al.,
1996). After experimental treatment, cells were exposed for 10 min to
FITC-annexin-V, using conditions recommended by the manufacturer
(Nexins Research), and confocal images of annexin-V fluorescence were
acquired.
Quantification of lipid peroxidation and HNE levels. The
thiobarbituric acid reactive substances (TBARS) method was used to assess membrane lipid peroxidation, as described previously (Goodman et
al., 1996); values were normalized to protein content. Levels of HNE
were quantified by dot-blot analysis. After experimental treatment,
culture medium was removed and stored at  80°C. Cells were washed
three times with PBS, scraped in a lysis buffer containing 0.1% SDS,
and sonicated. Samples (50 µl of medium; or 106
cells, which corresponds to ~50 µl cell volume) were blotted onto a
nitrocellulose sheet with a dot-blot apparatus (Bio-Rad, Hercules, CA);
a standard curve was generated by medium or cell homogenates containing
HNE at concentrations ranging from 0.1-5 µM. Then the
membrane was washed with TTBS, blocked by incubation in the presence of
5% milk, exposed to HRP-conjugated anti-mouse secondary antibody, and
detected by a chemiluminescence kit (Amersham, Arlington Heights, IL).
Densitometric analysis of dots in images of the blots was used to
calculate levels of HNE. It should be noted that this dot-blot method
is not truly quantitative and that the values reported are only an
estimate of the actual HNE levels.
Immunocytochemistry and Western blot analyses. Methods for
Western blot and immunocytochemical analyses of HNE-protein conjugates were similar to those described previously (Waeg et al., 1996; Mark et
al., 1997). For immunostaining, cultured cells were fixed for 30 min in
4% paraformaldehyde/PBS, and membranes were permeabilized by
incubation in 0.2% Triton X-100 in PBS. Cells were incubated for 1 hr
in blocking serum (1% normal horse serum in PBS), for 3 hr in the
presence of anti-HNE mouse monoclonal antibody (1:100 in PBS), for 1 hr
in PBS containing biotinylated horse anti-mouse secondary antibody, and
for 30 min in ABC reagent (Vector Laboratories, Burlingame, CA). Levels
of cellular immunoreactivity were assessed by using a semiquantitative
method described previously (Mattson, 1992); staining intensity of cell
bodies was scored on a scale from 0 to 3 (0, no staining; 1, weak
staining; 2, moderate staining; 3, intense staining). A total of 400 cells in four separate cultures per condition (100 cells/culture) were
scored in a blinded manner without knowledge of their treatment
history. For Western blot analysis, solubilized cell proteins were
separated by electrophoresis in a 10% polyacrylamide gel, transferred
to a nitrocellulose sheet, and immunoreacted with an antibody against
HNE-conjugated proteins (clone 1 g4; Waeg et al., 1996); The
nitrocellulose sheet was processed further with HRP-conjugated
anti-mouse secondary antibody and a chemiluminescence detection method
(Amersham).
Assessments of mitochondrial function. The conversion of the
dye MTT to formazan crystals in cells has been shown to be related to
mitochondrial respiratory chain activity (Musser and Oseroff, 1994) and
mitochondrial redox state (Shearman et al., 1995). Levels of cellular
MTT reduction were quantified as described previously (Mattson et al.,
1995b). The dye rhodamine 123 was used as a measure of mitochondrial
transmembrane potential by methods described previously (Mattson et
al., 1993).
Quantification of GSH levels. Two methods were used to
quantify cellular GSH levels. The first method used monochlorobimane, a
fluorescent probe for GSH (Barhoumi et al., 1995), and procedures described in our previous study (Kane et al., 1993). The second method
was based on an enzymatic recycling procedure in which GSH is oxidized
sequentially by 5,5 -dithiobis-(2-nitrobenzoic acid) (DTNB) and reduced
by NADPH in the presence of glutathione reductase and followed a
protocol similar to that reported by Tietze (1969). A GSH standard
curve was generated by analysis of serial dilutions of pure GSH. GSH
levels were adjusted to sample protein content (determined with a
Pierce BCA kit, Rockford, IL), and values were expressed as U/mg
protein.
RESULTS
Oxidative insults and HNE induce delayed apoptosis in
PC12 cells
Cultured control (PC12-V) and Bcl-2-expressing (PC12-Bcl2) PC12
cells were exposed to increasing concentrations of
FeSO4, A, and HNE, and mitochondrial function and
cell survival were quantified by MTT and trypan blue exclusion assays,
respectively. FeSO4 and A are known to induce lipid
peroxidation and to kill cultured neurons (Poli et al., 1985; Zhang et
al., 1993; Behl et al., 1994; Goodman and Mattson, 1994; Muller and
Krieglstein, 1995; Goodman et al., 1996). Exposure of PC12-V or
PC12-Bcl2 cells to high concentrations of FeSO4,
A, and HNE resulted in rapid decreases in levels of MTT reduction to
<20% of basal levels within 6 hr of exposure (Fig.
1A,B). Exposure of PC12-V cells to
lower concentrations of each insult (1 mM
FeSO4, 50 µM A, or 10 µM HNE) resulted in a moderate (20-30%) decrease in
levels of MTT reduction during the first 12-24 hr; values stayed at
this level through 48 hr of exposure and then decreased further (to
10-30% of basal levels) during a subsequent 24 hr period. In
contrast, levels of MTT reduction were maintained at 80-90% of basal
levels in PC12-Bcl2 cells exposed to the lower concentrations of
FeSO4, A, and HNE throughout the entire 72 hr
exposure period (Fig. 1A,B). Using rhodamine 123 fluorescence as an indicator of mitochondrial transmembrane potential
(Mattson et al., 1993), we found that 10 µM HNE caused a
significant (>50%) decrease in rhodamine 123 fluorescence in PC12-V
cells, but not in PC12-Bcl2 cells, during a 24 hr exposure period (data
not shown). High concentrations of FeSO4,
A25-35, and HNE induced relatively rapid cell death in both PC12-V
and PC12-Bcl2 cells that occurred within 12-24 hr of exposure (Fig.
1C,D). Lower concentrations of FeSO4,
A, and HNE induced delayed uptake of trypan blue in PC12-V cells that occurred 48-72 hr post-treatment; the delayed uptake of trypan blue likely was attributable to secondary necrosis (Slater et al.,
1995). In contrast to PC12-V cells, PC12-Bcl2 cells were not killed by
the lower concentrations of FeSO4, A, or HNE
(Fig. 1C,D), consistent with an apoptotic mechanism of cell
death.
Fig. 1.
Oxidative insults and HNE induce rapid and delayed
cell death in PC12 cells: Bcl-2 prevents delayed cell death.
A, B, PC12-V (A)
and PC12-Bcl2 (B) cells were exposed to the
indicated concentrations of HNE, A, or FeSO4 for the
indicated time periods, and levels of MTT reduction were quantified
(mean and SEM of determinations made in four culture wells/condition).
C, D, PC12-V cells
(C) and PC12-Bcl2 cells (D)
were exposed to vehicle (Control) or the indicated concentrations of HNE, A, or
FeSO4, and trypan blue-positive and
nonstaining cells were counted. Values are the mean percentage of
trypan blue-positive cells in four separate cultures.
[View Larger Version of this Image (37K GIF file)]
To establish whether the delayed cell death induced by oxidative
insults and HNE in PC12-V cells was apoptotic, we examined nuclear
condensation and fragmentation by using fluorescent DNA-binding dyes
Hoescht 33342 and propidium iodide (Fig. 2). Exposure of PC12-V cells to concentrations of FeSO4, A, and
HNE that caused delayed death resulted in the appearance of many cells
exhibiting nuclear condensation and fragmentation, which occurred
progressively beginning at ~30 hr post-treatment (Fig.
2A,D). In contrast, no PC12-Bcl2 cells exhibited
nuclear signs of apoptosis during the 72 hr exposure period to
FeSO4, A, or HNE. An early event in apoptosis is
a loss of plasma membrane asymmetry, resulting in the exposure of
phosphatidylserine on the cell surface, which binds annexin-V (Martin
et al., 1995). In control PC12-V cultures annexin-V-positive cells were
rare (<5% of the cells). When PC12-V cells were exposed to 10 µM HNE, there was a relatively rapid and progressive
appearance of annexin-V-positive cells such that ~25 and 45% of the
cells were annexin-V-positive by 4 and 16 hr post-treatment,
respectively (Fig. 2B). Confocal images suggested that the annexin-V was associated with the cell surface (data not
shown). Because several aldehydes are liberated when membrane lipids
are peroxidized, we determined whether other aldehydes also induce
apoptosis. Among nine different aldehydes examined (HNE, propanal,
pentanal, hexanal, heptanal, nonenal, malondialdehyde, nonaldehyde, and
trans-2-nonenal), only HNE induced nuclear condensation and
DNA fragmentation (Fig. 2C) and annexin-V binding (data not shown).
Fig. 2.
Oxidative insults and HNE induce apoptotic nuclear
and plasma membrane alterations in PC12 cells: prevention by Bcl-2.
A, Cultures of PC12-V cells and PC12-Bcl2 cells were
exposed to vehicle (Control) or the indicated
concentrations of HNE, A, or
FeSO4. At the indicated time points cells
were stained with Hoescht dye, and the percentage of cells with
condensed and fragmented (apoptotic) nuclei was determined (mean and
SEM of determinations made in four separate cultures). No cells
expressing Bcl-2 exhibited condensed and fragmented nuclei (PC12-Bcl2
line represents combined data from cells exposed to each
treatment condition). B, Annexin-V-positive cells were
counted in PC12-V and PC12-Bcl2 cultures exposed for 4 hr to 10 µM HNE or for 16 hr to vehicle
(Control) or 10 µM HNE. Values are
the mean and SEM of determinations made in four separate cultures.
*p < 0.001 compared with values for control
cultures and PC12-Bcl2 cultures (ANOVA with Scheffé's
post hoc tests). C, PC12-V cell cultures
were exposed for 48 hr to vehicle (Control) or
the indicated aldehydes (10 µM). Cells were stained with
Hoescht dye, and the percentages of cells with condensed and fragmented nuclei were determined. Values are the mean and SEM of determinations made in four separate cultures. *p < 0.001 compared with each of the other values (ANOVA with Scheffé's
post hoc tests). D, Confocal laser
scanning microscope images of propidium iodide fluorescence in
untreated control PC12-V cells (left), PC12-V cells
exposed for 48 hr to 10 µM HNE (middle),
and PC12-Bcl-2 cells exposed for 48 hr to 10 µM HNE
(right). Note that many PC12-V cells treated with HNE
exhibit DNA condensation and fragmentation (arrowheads),
whereas cells expressing Bcl-2 did not.
[View Larger Version of this Image (100K GIF file)]
Macromolecular synthesis inhibitors and endonuclease inhibitors can
prevent apoptosis (Bastitatou and Greene, 1991; Rukenstein et al.,
1991). Nuclear condensation and fragmentation induced by HNE,
FeSO4, and A was prevented mainly in PC12-V
cultures cotreated with either the protein synthesis inhibitor
cycloheximide, the RNA synthesis inhibitor actinomycin-D, or the
Ca2+-Mg2+-dependent endonuclease
inhibitor aurintricarboxylic acid (ATA; Table 1).
Table 1.
Effects of macromolecular synthesis inhibitors, an
endonuclease inhibitor, and antioxidants on apoptotic cell death
induced by oxidative insults and HNE in PC12 cells
| Insult |
Vehicle |
Cells with
apoptotic nuclei (%)
|
| Cyclohex |
Act-D |
ATA |
VitE |
PG
|
|
| Cont (2 hr) |
3 ± 1.2 |
1
± 0.3 |
2 ± 0.6 |
1 ± 0.3 |
0 ± 0.3 |
1 ± 0.3
|
| Cont (72 hr) |
24 ± 4.7 |
11 ± 2.5 |
10 ± 3.3 |
9
± 2.4 |
10 ± 2.1 |
13 ± 3.1 |
| FeSO4 |
75
± 3.2* |
16 ± 2.7** |
22 ± 3.3** |
13 ± 3.3** |
13
± 2.8** |
21 ± 2.1** |
| A |
72 ± 3.3* |
21
± 3.4** |
23 ± 4.3** |
12 ± 2.2** |
11 ± 3.5** |
14
± 3.2** |
| HNE |
71 ± 6.7* |
29 ± 4.3** |
29
± 4.0** |
26 ± 3.2** |
59 ± 3.3 |
65 ± 3.8 |
|
|
Cultures were pretreated for 2 hr with the indicated agents:
0.2% ethanol (Vehicle), 10 µM cycloheximide (Cyclohex),
5 µM actinomycin-D (Act-D), 100 µM
aurintricarboxylic acid (ATA), 50 µg/ml vitamin E (VitE), 10 µM propyl gallate (PG), or 1 mM
glutathione-ethyl ester (GSH). Some cultures were fixed at that point
(Cont, 2 hr), while parallel cultures were exposed for 72 hr to 0.2%
ethanol (Cont 72 hr), 1 mM FeSO4, 50 µM A, or 10 µM HNE. Cells then were fixed and stained with Hoescht dye, and percentages of cells exhibiting nuclear condensation and fragmentation were determined. Values are the
mean and SEM of determinations made in three or four separate cultures.
*
p < 0.001 compared with value for control
vehicle-treated (72 hr) cultures;
**
p < 0.01 compared
with value for vehicle-treated cultures exposed to the same insult.
ANOVA with Scheffé's post hoc tests. Preliminary
studies showed that 10 µM cycloheximide reduced levels of
protein synthesis by >90% during a 24 hr exposure period (data not
shown).
|
|
Oxidative insults and HNE induce apoptosis in hippocampal neurons:
protection by GSH
Although studies of PC12 cells have provided valuable insight into
mechanisms of neural cell apoptosis (Bastitatou and Greene, 1991;
Rukenstein et al., 1991; Ferrari et al., 1995; Troy et al., 1996a),
PC12 cells do not exhibit several important features of primary
neurons, including expression of glutamate receptors and synapse
formation. We therefore turned to mature primary hippocampal cell
cultures. Whereas <5% of hippocampal neurons exhibited apoptotic nuclei in vehicle-treated control cultures, 70-80% of the neurons exhibited nuclear condensation and fragmentation in cultures exposed to
2 µM HNE (Fig. 3). Lower concentrations of
HNE caused progressively less apoptotic neuronal death (0.5 µM HNE, 18 ± 3.0%; 1 µM HNE, 49 ± 4.1%; n = 4 cultures), whereas higher levels (5-10
µM) induced rapid necrosis (data not shown). Eight other
aldehydes (2 µM) did not induce apoptosis (Fig.
3A) or necrosis (data not shown). A and FeSO4
also induced apoptosis in the cultured hippocampal neurons (Fig.
3B). Previous studies showed that GSH can conjugate with,
and thereby detoxify, HNE in non-neuronal cells (Spitz et al., 1990).
Pretreatment of hippocampal cultures with a membrane-permeant form of
GSH (GSH-diethyl ester) afforded significant protection against
apoptosis induced by each oxidative insult and HNE (Fig. 3B).
Fig. 3.
Oxidative insults and HNE induce apoptosis
in primary hippocampal neurons: prevention by GSH. A,
Cultures were exposed to 2 µM of each aldehyde (see
Fig. 2C for aldehyde structures) or 0.2% ethanol
(Control) for 16 hr, and percentages of neurons
with condensed and fragmented nuclei were quantified. Values are the mean and SEM of determinations made in four separate cultures. *p < 0.05, **p < 0.001 compared with control value (ANOVA with Scheffé's post
hoc tests). B, Cultures were exposed for 16 hr to 0.2% ethanol (Control) or the indicated
treatments, at which time cells were stained with Hoescht dye and the
percentages of neurons with condensed and fragmented nuclei were
quantified. Treatment concentrations were HNE, 10 µM; A, 10 µM;
FeSO4, 2 µM;
GSH, 1 mM. Values are the mean and SEM of
determinations made in four separate cultures. *p < 0.01 compared with control value; **p < 0.01, ***p < 0.05 compared with corresponding values for cultures not cotreated with GSH (ANOVA with Scheffé's
post hoc tests). C, Images of Hoescht dye
fluorescence in hippocampal neurons from cultures exposed for 16 hr to
0.2% ethanol (Control), 2 µM HNE, 1 mM GSH-ethyl-ester plus 2 µM HNE (GSH+HNE), or 10 µM
A. HNE and A induced nuclear condensation and
fragmentation in most neurons (arrowheads), whereas
fluorescence remained uniformly distributed throughout the nucleus in
neurons in control cultures and neurons in cultures cotreated with GSH
and HNE (arrowheads).
[View Larger Version of this Image (1K GIF file)]
Oxidative insults induce lipid peroxidation and formation
of HNE-protein conjugates in neural cells: suppression by GSH and
Bcl-2
A TBARS fluorescence assay, which measures malondialdehyde levels
(Kovachich and Mishra, 1980), was used to quantify membrane lipid
peroxidation. Exposure of PC12-V cells or hippocampal neurons to
apoptotic concentrations of FeSO4 and A resulted in
marked increases in TBARS fluorescence (Fig.
4A). HNE did not affect TBARS levels
in either cell type, consistent with its being a downstream effector of
oxidative stress-induced apoptosis rather than an initiator of
oxidative stress. If HNE mediates oxidative stress-induced apoptosis,
then the oxidative insults should induce HNE accumulation in neurons to
levels capable of inducing apoptosis. HNE levels were measured with an
anti-HNE antibody (Waeg et al., 1996) in dot-blot, immunocytochemical,
and Western blot assays. Hippocampal cells were exposed to 2 µM FeSO4 or 1 µM HNE, and levels of HNE in the culture medium and cells were quantified at
increasing time points after treatment. FeSO4 induced a
time-dependent increase in HNE levels in the cells; levels reached ~1
µM 30 min after exposure, increased to nearly 3 µM 6 hr post-treatment, and then decreased to ~2
µM by 24 hr post-treatment (Fig. 4B). HNE was not detectable in the medium (<0.1 µM) at any
time point after exposure of cultures to FeSO4. When 1 µM HNE was added to the cultures, HNE levels in cells
increased to ~2 µM during the first 2 hr and then
decreased somewhat during the next 22 hr; HNE levels in the culture
medium remained at ~1 µM during the first 2 hr and then
progressively decreased through 24 hr (Fig. 4B).
Fig. 4.
Oxidative insults induce membrane lipid
peroxidation in neural cells: suppression by Bcl-2. A,
Levels of TBARS fluorescence were quantified in PC12-V cells, PC12-Bcl2
cells, and hippocampal neurons after 4 hr of exposure to vehicle
(Control), FeSO4 (1 mM PC12 cells, 2 µM hippocampal neurons),
A (50 µM PC12 cells, 10 µM hippocampal neurons), or HNE (10 µM PC12 cells, 2 µM hippocampal neurons).
Values represent the mean and SEM of determinations made in four to six
separate cultures. B, Hippocampal cell cultures were
exposed to 1 µM HNE or 2 µM
FeSO4, and HNE levels in the culture medium and
cells were quantified at the indicated time points.
Values represent the mean and SEM of determinations made in four
separate cultures.
[View Larger Version of this Image (27K GIF file)]
Immunocytochemical analyses showed that oxidative insults and HNE
induced HNE immunoreactivity in cultured hippocampal neurons and PC12-V
cells (Fig. 5). The levels of cellular HNE
immunoreactivity after exposure to FeSO4, A, and
HNE were reduced greatly in hippocampal cells pretreated with GSH, as
compared with control cells (Fig. 5A,D). Exposure of PC12-V
cells to FeSO4, A, and HNE for 12 hr resulted in
the appearance of HNE immunoreactivity in essentially all cells; in
most cells the HNE immunoreactivity appeared to be concentrated in
perinuclear regions and at the cell periphery, suggesting plasma
membrane and organellar localizations (Fig. 5B,D). In
contrast, levels of HNE immunoreactivity in PC12-Bcl2 cells exposed to
A, FeSO4, and HNE were reduced markedly, as compared with levels in PC12-V cells exposed to the same insults (Fig.
5B,D). To determine whether HNE production occurs in all apoptotic paradigms or is specific for oxidative insults, we exposed PC12-V cells for 2, 6, 12, or 24 hr to an apoptotic concentration of
staurosporine (500 nM) and then immunostained the cells
with the HNE antibody. No detectable HNE immunoreactivity was observed at any time point after exposure to staurosporine (data not shown).
Fig. 5.
Oxidative insults induce formation of HNE-protein
conjugates in neural cells: attenuation by GSH and Bcl-2.
A, Hippocampal cultures were exposed for 2 hr to 0.2%
ethanol (Control), 2 µM FeSO4, 2 µM
HNE, or 1 mM GSH plus 2 µM HNE
(GSH+HNE). Then cells were fixed and immunostained with
HNE antibody. Arrowheads point to neuronal cell bodies.
B, PC12-V cells and PC12-Bcl-2 cells were exposed for 2 hr to vehicle (0.2% ethanol) or 10 µM HNE. Then cells
were fixed and immunostained with anti-HNE antibody. Note the much
greater level of HNE immunoreactivity in PC12-V cells exposed to HNE,
as compared with PC12-Bcl-2 cells exposed to HNE. C,
Cell homogenates from untreated control PC12-V cultures (c), PC12-V
cultures exposed to 10 µM HNE or 1 mM
FeSO4 (v), and PC12-Bcl2 cultures exposed to
10 µM HNE or 1 mM FeSO4
(b) were separated by SDS-PAGE (100 µg protein/lane).
Then proteins were transferred to a nitrocellulose sheet and
immunoreacted with an antibody against HNE-protein conjugates. Note
that HNE and FeSO4 induced the appearance of many
HNE-protein conjugates in PC12-V cells, but not in the PC12-Bcl2
cells. D, PC12-V cells, PC12-Bcl2 cells, and primary
hippocampal neurons were exposed for 2 hr to 0.2% ethanol
(Control), FeSO4 (1 mM for PC12 cells and 2 µM for hippocampal
neurons), A (50 µM for PC12 cells and
10 µM for hippocampal neurons), or HNE (10 µM for PC12 cells and 2 µM for hippocampal neurons). Then cells were fixed and immunostained with HNE antibody, and relative levels of HNE immunoreactivity were quantified (see Materials and Methods). Values represent the mean and SEM of
determinations made in four separate cultures per condition (100 cells
scored/culture).
[View Larger Version of this Image (92K GIF file)]
Western blot analysis of PC12-V and PC12-Bcl2 cells exposed for 12 hr
to vehicle, FeSO4, or HNE showed that, whereas there were no detectable HNE-protein conjugates in control cultures, there
were many proteins immunoreactive with the HNE antibody in PC12-V cells
exposed to HNE or FeSO4 (Fig. 5C). The pattern of HNE-protein conjugates in proteins from cells exposed directly to
HNE were similar, but not identical, to the pattern seen in cells
exposed to FeSO4. Although the basis for the differences in
banding was not established, it seems likely that proteins located in
the plasma membrane are exposed to locally higher concentrations of HNE
in cells exposed to FeSO4 (compared with cells exposed to
exogenous HNE) because that is where the endogenous HNE comes from. In
contrast to PC12-V cells, only very low levels of HNE-protein conjugates were present in Western blots of proteins from PC12-Bcl2 cells exposed to either FeSO4 or HNE (Fig. 5C).
In additional experiments we performed electron paramagnetic
spectroscopy analyses with nitroxyl stearate spin labels to quantify
lipid peroxidation; the results confirmed that Bcl-2 suppresses lipid
peroxidation induced by iron and A in PC12 cells (data not shown;
cf. Bruce et al., 1995).
Pretreatment of PC12-V cultures with the antioxidants vitamin E and
propyl gallate before exposure to FeSO4 and A resulted in significant protection against apoptosis induced by these oxidative insults (Table 1). In contrast, vitamin E and propyl gallate did not
protect PC12-V cells against HNE-induced apoptosis (Table 1),
consistent with HNE acting as a downstream effector of lipid peroxidation-induced apoptosis.
Evidence that endogenous GSH serves an antiapoptotic function
The ability of GSH to protect hippocampal neurons against
apoptosis induced by oxidative stress and HNE prompted studies of possible antiapoptotic actions of endogenous GSH. When PC12-V cells
were pretreated with 1 mM GSH diethyl ester, they were
resistant to apoptosis induced by FeSO4, A, and
HNE (Fig. 6A). Whereas ~80% of the
cells exhibited apoptotic nuclei after exposure to FeSO4, A, and HNE, only 15-40% of the cells
were apoptotic in cultures cotreated with GSH. BSO, an agent that
depletes endogenous GSH by inhibiting  -glutamyl cysteine synthetase
(Meister, 1995), induced apoptosis in PC12-V cells, suggesting that
depletion of GSH was sufficient to induce apoptosis (Fig.
6A). Previous studies have shown that cell expressing
Bcl-2 exhibit higher GSH levels than control cells and show less GSH
depletion when exposed to oxidative apoptotic insults (Ellerby et al.,
1996; Hedley and McCulloch, 1996). GSH levels quantified by the
monochlorobimane method were 30-40% greater in PC12-Bcl2 cells, as
compared with PC12-V cells (Fig. 6B). After exposure
to A, FeSO4, and HNE, levels of GSH were
decreased significantly by 40-70% in PC12-V cells (Fig.
6B). The levels of GSH in PC12-Bcl2 cells after
exposure to A and FeSO4 were significantly greater than
in PC12-V cells exposed to the same insults. Similar results were
obtained with the enzymatic recycling procedure for quantification of
GSH levels (data not shown). As expected, BSO caused a marked depletion
of GSH levels in both PC12-V and PC12-Bcl2 cells; GSH levels remained at a higher level in PC12-Bcl2 cells than in PC12-V cells, although the
difference was not statistically significant (Fig.
6B).
Fig. 6.
GSH protects PC12 cells against apoptosis
induced by oxidative insults and HNE. A, Cultures of
PC12-V cells were exposed for 70 hr to Vehicle, 10 µM HNE, 50 µM
A, or 1 mM
FeSO4 in the absence (Control) or presence of 1 mM
GSH. Then cultures were fixed and stained with Hoescht
dye, and the numbers of cells with condensed and fragmented nuclei were
counted. Values are the mean and SEM of determinations made in four
separate cultures. *p < 0.01 compared with vehicle
control value; **p < 0.01 compared with
corresponding control value (ANOVA with Scheffé's post
hoc tests). B, Cultures were exposed for 6 hr to
vehicle (Cont), 50 µM A,
1 mM FeSO4, 10 µM HNE, or 300 µM buthionine
sulfoximine (BSO). Then relative levels of GSH were
determined by using the monochlorobimane fluorescence method. Values
are the mean and SEM of determinations made in four separate cultures.
*p < 0.01 compared with corresponding value for
PC12-V cells (ANOVA with Scheffé's post hoc
tests).
[View Larger Version of this Image (33K GIF file)]
DISCUSSION
The present findings demonstrate that the lipid peroxidation
product HNE can induce apoptosis in PC12 cells and primary rat hippocampal neurons and suggest that HNE is a mediator of oxidative stress-induced apoptosis. HNE induced loss of plasma membrane phosphatidylserine asymmetry (detected by annexin-V binding) and nuclear condensation and DNA fragmentation in PC12 cells and
hippocampal neurons. HNE-induced cell death was prevented by
cycloheximide, actinomycin-D, and aurintricarboxylic acid, consistent
with a role for macromolecular synthesis and endonuclease activity in the cell death process. Although we recently reported that low concentrations of cycloheximide that do not cause sustained blockade of
protein synthesis can protect neurons against excitotoxic and oxidative
insults by a mechanism that apparently involves stimulation of
antioxidant pathways (Furukawa et al., 1997), the concentration of
cycloheximide used in the present study (10 µM) causes an
essentially complete and sustained blockade of protein synthesis
(Furukawa et al., 1997). In addition, PC12 cells expressing the
antiapoptotic gene product Bcl-2 were resistant to apoptosis induced by
HNE. The concentrations of HNE that induced apoptosis (2-10
µM, estimated from dot-blot analyses) are within the
range of concentrations (1-100 µM) known to be generated
after exposure of non-neuronal cells (Esterbauer et al., 1991) and
neurons (Mark et al., 1997) (present study) to oxidative insults. Among
aldehydic products of lipid peroxidation, HNE seems to be a unique
inducer of apoptosis, because eight other aldehydes did not induce
apoptosis in PC12 cells or hippocampal neurons. These findings are
consistent with a recent report showing that HNE, but not other
aldehydes, is toxic to cultured human neuroblastoma cells (Mark et al.,
1997).
Apoptotic concentrations of FeSO4 and A induced the
formation of HNE-protein conjugates, as detected by both Western blot and immunocytochemical analyses. Antioxidants that suppress lipid peroxidation protected PC12 cells against apoptosis induced by FeSO4 and A but did not protect against apoptosis
induced by HNE, consistent with HNE acting downstream of lipid
peroxidation in the apoptotic pathway induced by oxidative stress. GSH,
which was shown previously to detoxify HNE (Spitz et al., 1990;
Esterbauer et al., 1991), protected PC12 cells and hippocampal neurons
against apoptosis induced by HNE and oxiative
insults. Beaver and Waring (1995) reported that decreases in levels of
intracellular GSH precede apoptosis in mouse thymocytes exposed to
dexamethasone, thapsigargin, and gliotoxin; treatment with 1 mM GSH prevented apoptosis, suggesting a role for GSH
depletion in the apoptotic process. Ratan et al. (1994) showed that
macromolecular synthesis inhibitors prevent oxidative stress-induced
apoptosis in cultured cortical neurons by increasing GSH levels. We
found that GSH levels were higher in PC12 cells expressing Bcl-2 than
in PC12-V cells in untreated cultures and after exposure to A,
FeSO4, and HNE. Collectively, the data suggest that
endogenous GSH may contribute to the resistance of cells expressing
Bcl-2 to oxidative insults.
Levels of TBARS fluorescence and HNE-protein conjugates induced by
FeSO4 and A were lower in PC12 cells expressing Bcl-2, consistent with data showing that Bcl-2 suppresses lipid peroxidation induced by oxidative insults in a hypothalamic tumor cell line (Kane et
al., 1993; Myers et al., 1995) and PC12 cells (present study). On the
other hand, levels of HNE-protein conjugates resulting from exposure
of cells to HNE also were reduced in PC12 cells expressing Bcl-2,
suggesting that Bcl-2 suppresses formation of HNE-protein conjugates.
An increased level of GSH in cells expressing Bcl-2 could account for
our results because GSH plays a central role in the cellular metabolism
of HNE (Ishikawa et al., 1986; Spitz et al., 1990). In studies of
spinal cord organotypic cultures, Rothstein et al. (1994) showed that
downregulation of Cu/Zn-SOD resulted in neuronal apoptosis, which was
inhibited by antioxidants. Troy et al. (1996b) reported that
downregulation of Cu/Zn-SOD in PC12 cells induces apoptosis, which can
be prevented with inhibitors of nitric oxide synthase, suggesting the
involvement of peroxynitrite. When taken together with our data, the
latter findings suggest that there may be at least two mechanisms
whereby oxidative stress induces apoptosis, one involving nitric oxide
production and peroxynitrite formation and the other involving hydroxyl
radical formation, lipid peroxidation, and HNE production. However, the
two pathways likely converge at some point because Bcl-2 prevents
apoptosis in both cases. Because peroxynitrite is known to induce
membrane lipid peroxidation, it will be of interest to determine
whether HNE plays a role in apoptotic paradigms that involve nitric
oxide production and peroxynitrite formation and, conversely, whether there is a role for peroxynitrite in HNE-induced apoptosis.
Loss of cellular ion homeostasis plays a central role in excitotoxic
neuronal death and also may contribute to oxidative stress-induced apoptosis. HNE increases neuronal vulnerability to excitotoxicity (Mark
et al., 1997), and loss of calcium homeostasis has been implicated in
the apoptotic process in a number of paradigms (Nicotera et al., 1992;
Takei and Endo, 1994; Le et al., 1995). Recent findings indicate that
neuronal death induced by excitotoxins or oxidative insults can
manifest as either apoptosis or necrosis, depending on the severity of
the insult (Ankarcrona et al., 1995; Bonfoco et al., 1995) (present
study). Although not directly tested in the present study, disruption
of calcium homeostasis may contribute to oxidative stress-induced
apoptosis. FeSO4, A, and HNE each cause
impairment of ion-motive ATPase activities in cultured hippocampal neurons, which is linked to subsequent elevation of
[Ca2+]i and cell death (Mark et al.,
1995, 1997). The ability of ATA to protect PC12 cells against
HNE-induced apoptosis is consistent with a role for calcium in that ATA
is an inhibitor of calcium-activated endonucleases (Zhivotovsky et al.,
1994) and calpains (Posner et al., 1995), although it may have other
actions, also (Zeevalk et al., 1995).
Mitochondrial alterations, including decreases in transmembrane
potential and decreased levels of MTT reduction, occur at relatively
early stages in the apoptotic process (Zamzami et al., 1996). We found
that apoptotic concentrations of A, FeSO4, and A each caused a relatively rapid (2-6 hr) small decrease in levels of MTT reduction and mitochondrial transmembrane potential. Shearman et
al. (1995) also found that A rapidly decreases levels of MTT reduction in PC12 cells. Interestingly, the initial modest decrease in
levels of MTT reduction occurred in both PC12-V and PC12-Bcl2 cells
exposed to oxidative insults and HNE, suggesting that this early
mitochondrial alteration is not linked causally to subsequent apoptotic
death. Indeed, previous data indicate that functioning mitochondria
(and resultant ATP) are required for apoptosis (Slater et al., 1995).
HNE also impairs mitochondrial function in synaptosomes (Keller et al.,
1997), and GSH attenuates oxidative stress-induced disruption of
mitochondrial transmembrane potential in lymphocytes (Pieri et al.,
1995), suggesting that HNE contributes to oxidative stress-induced
mitochondrial dysfunction.
HNE fulfills several criteria for a mediator of oxidative
stress-induced apoptosis, including the following: HNE is produced in
neurons exposed to apoptotic oxidative insults, HNE itself can induce
apoptosis, and an inhibitor of HNE (GSH) protects neurons against
oxidative stress- and HNE-induced apoptosis. Because essentially all
vertebrate cells are capable of generating HNE in response to oxidative
insults, HNE may serve a general role in apoptosis in many different
organ systems. Because it can move readily across membranes and through
cells, HNE has the ability to induce alterations in subcellular sites
affected in cells undergoing apoptosis. Indeed, HNE has been reported
to damage both proteins and DNA (Esterbauer et al., 1991; Martelli et
al., 1994).
Finally, our data suggest possible roles for HNE in the pathogenesis of
neurodegenerative disorders such as AD and Parkinson's disease, in
which apoptosis may occur (Loo et al., 1993; Su et al., 1994; Stern,
1996). Very recent findings indicate that levels of protein-bound HNE
are increased selectively in neurons in the substantia nigra of
Parkinson's patients (Yoritaka et al., 1996) and that levels of free
HNE are increased more than twofold in CSF of AD patients (M. A. Lovell
and W. R. Markesbery, personal communication). Therefore, further
studies of roles of HNE in apoptotic neuronal death are warranted to
clarify its role in neurodegenerative disorders.
FOOTNOTES
Received Feb. 21, 1997; revised April 4, 1997; accepted April 23, 1997.
This work was supported by Grants to M.P.M. from the National
Institutes of Health (NS30583 and AG10836), the Alzheimer's Association (Zenith Award), and the Metropolitan Life Foundation; to
D.E.B. from National Institutes of Health (AG12282 and NS25554); and to
I.K. by a National Institute on Aging training grant fellowship. We
thank J. G. Begley, S. Bose, W. Fu, Y. Goodman, and R. Pelphrey for
technical assistance.
Correspondence should be addressed to Dr. Mark P. Mattson, 211 Sanders-Brown Building, University of Kentucky, Lexington, KY
40536-0230.
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