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The Journal of Neuroscience, November 15, 1999, 19(22):9821-9830
Protection from Oxidative Stress-Induced Apoptosis in Cortical
Neuronal Cultures by Iron Chelators Is Associated with Enhanced DNA
Binding of Hypoxia-Inducible Factor-1 and ATF-1/CREB and Increased
Expression of Glycolytic Enzymes, p21waf1/cip1, and
Erythropoietin
Khalequz
Zaman1,
Hoon
Ryu1,
David
Hall1,
Kevin
O'Donovan5,
Kuo-I
Lin1,
Matthew P.
Miller1,
John C.
Marquis3,
Jay M.
Baraban5, 7,
Gregg L.
Semenza4, 6, and
Rajiv
R.
Ratan1, 2
1 Department of Neurology and 2 Program in
Neuroscience, Harvard Medical School and The Beth Israel Deaconess
Medical Center, Boston, Massachusetts 02115, 3 Department
of Cancer Cell Biology, Harvard School of Public Health, Boston,
Massachusetts, and 4 Institute of Genetic Medicine
and Departments of 5 Neuroscience,
6 Pediatrics, and 7 Psychiatry and Behavioral
Science, Johns Hopkins University School of Medicine, Baltimore,
Maryland
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ABSTRACT |
Iron chelators are pluripotent neuronal antiapoptotic agents that
have been shown to enhance metabolic recovery in cerebral ischemia
models. The precise mechanism(s) by which these agents exert their
effects remains unclear. Recent studies have demonstrated that iron
chelators activate a hypoxia signal transduction pathway in
non-neuronal cells that culminates in the stabilization of the
transcriptional activator hypoxia-inducible factor-1 (HIF-1) and
increased expression of gene products that mediate hypoxic adaptation.
We examined the hypothesis that iron chelators prevent oxidative
stress-induced death in cortical neuronal cultures by inducing
expression of HIF-1 and its target genes. We report that the
structurally distinct iron chelators deferoxamine mesylate and mimosine
prevent apoptosis induced by glutathione depletion and oxidative stress
in embryonic cortical neuronal cultures. The protective effects of iron
chelators are correlated with their ability to enhance DNA binding of
HIF-1 and activating transcription factor 1(ATF-1)/cAMP response
element-binding protein (CREB) to the hypoxia response element
in cortical cultures and the H19-7 hippocampal neuronal cell line. We
show that mRNA, protein, and/or activity levels for genes whose
expression is known to be regulated by HIF-1, including glycolytic
enzymes, p21waf1/cip1, and erythropoietin, are
increased in cortical neuronal cultures in response to iron chelator
treatment. Finally, we demonstrate that cobalt chloride, which also
activates HIF-1 and ATF-1/CREB in cortical cultures, also prevents
oxidative stress-induced death in these cells. Altogether, these
results suggest that iron chelators exert their neuroprotective
effects, in part, by activating a signal transduction pathway leading
to increased expression of genes known to compensate for hypoxic or
oxidative stress.
Key words:
iron chelators; oxidative stress; glutathione; apoptosis; HIF-1; ATF-1/CREB
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INTRODUCTION |
Disrupted iron homeostasis has been
linked to a number of neurodegenerative states (Connor and Menzies,
1995 ) including Alzheimer's disease (Smith et al., 1997; Lovell et
al., 1998), Parkinson's disease (Michel et al., 1992; Hartley et al.,
1993; Gassen and Youdim; 1997; Olanow, 1997; Hirsch and
Faucheux, 1998), stroke (Lipscomb et al., 1998), multiple
sclerosis (Levine, 1997), and Friedreich's ataxia (Babcock et al.,
1997; Rotig et al., 1997). The link between iron and the pathogenesis
of several neurodegenerative conditions provides a firm rationale for
the therapeutic use of small molecules, such as deferoxamine (DFO),
which chelate iron and prevent it from participating in deleterious
redox reactions. Indeed, DFO has been reported to slow progression of
Alzheimer's disease (Crapper McLachlan et al., 1991), to enhance
metabolic recovery in animal models of stroke (Hurn et al., 1995), and
to attenuate the severity and duration of experimental allergic
encephalomyelitis in rats (Bowern et al., 1984). Despite these
promising clinical and preclinical observations, the precise mechanisms
by which iron chelators prevent neuronal injury remain unclear.
Iron or other transition metals such as copper are believed to induce
neuronal injury by converting superoxide
(O2. ) and hydrogen
peroxide (H2O2) into highly
reactive, toxic hydroxyl radicals (OH.) in
a sequence of reactions that are referred to cumulatively as the
Haber-Weiss reaction (Winterbourn, 1995). According to this scheme,
iron chelators diminish hydroxyl radical formation and oxidative stress
by sequestering redox active iron. The abilities of structurally
distinct chelators to inhibit apoptosis induced by depletion of
superoxide dismutase in pheochromocytoma 12 (PC12) cells (Troy et al.,
1996) or by depletion of glutathione in oligodendrocytes (Yonezawa et
al., 1996) are consistent with the notion that iron chelators prevent
apoptotic cell death by reducing hydroxyl radical formation and
oxidative stress.
Recent studies, however, have identified novel pathways by which
iron chelators may enhance survival (Beckman et al., 1990). Apoptosis
induced by serum or growth factor deprivation of PC12 cells or
sympathetic neurons can be prevented by pretreatment with higher
concentrations of the iron chelators DFO and mimosine (MIM) than are
required to prevent oxidative stress-induced death (Farinelli and
Greene, 1996). In this paradigm, the protective effects of iron
chelators cannot be mimicked by antioxidants, including vitamin E. Rather, the protective effects of chelating iron correlate with
inhibition of proliferation. In this context, the antiproliferative
effects of iron chelators have been attributed to a decrease in cyclin
A/p34cdc2 kinase activity and mRNA levels (Terada et al., 1993; Feldman
and Schonthal, 1994).
Iron chelators have also been shown to activate a hypoxia stress
response pathway. DFO induces expression of hypoxia-inducible factor-1
(HIF-1) and transcription of downstream target genes including
erythropoietin (Wang and Semenza, 1993), glycolytic enzymes (Semenza et
al., 1994), and vascular endothelial growth factor (Levy et al.,
1995; Forsythe et al., 1996; Jiang et al., 1997). HIF-1 is a
heterodimer composed of HIF-1 (~120 kDa) and HIF-1 (91-94 kDa)
subunits that bind to the consensus sequence 5'-RCGTG-3' (Semenza,
1998). These studies highlight the diversity of cellular responses to
iron chelators and suggest that these pluripotent antiapoptotic agents
may act to enhance survival by mechanisms other than simply suppressing
hydroxyl radical formation. In this manuscript, we examine the
hypothesis that iron chelators exert their neuroprotective effects, in
part, by the enhancement of DNA binding of HIF-1 to the hypoxia
response element and the consequent upregulation of HIF-1-regulated
genes that provide resistance to oxidative or hypoxic stress.
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MATERIALS AND METHODS |
Primary neurons. Cell cultures were obtained from the
cerebral cortex of fetal Sprague Dawley rats [embryonic day 17 (E17)] as described previously (Murphy et al., 1990). All experiments were
initiated 24 72 hr after plating. Under
these conditions the cells are not susceptible to glutamate-mediated
excitotoxicity. For cytotoxicity studies, cells were rinsed with warm
PBS and then placed in Minimum Essential Medium (MEM; Life
Technologies, Gaithersburg, MD) with 5.5 gm/l glucose, 10% FCS, 2 mM L-glutamine, and 100 µM
cystine, containing the glutamate analog homocysteate (HCA; 1 mM). HCA was diluted from 100-fold concentrated solutions
that were adjusted to pH 7.5. Viability was assessed by phase-contrast
microscopy, lactate dehydrogenase (LDH) release (Koh and Choi, 1987;
Ratan et al., 1994a,b), calcein AM/ethidium homodimer-1 staining
(Molecular Probes, Eugene, OR) under fluorescence microscopy, or trypan
blue exclusion. To evaluate the effects of iron chelators on
cytotoxicity, we added deferoxamine mesylate (1-500 µM;
Sigma, St. Louis, MO) or mimosine (1-500 µM;
Sigma) at the time cortical neurons were exposed to HCA or up to
10 hr after HCA treatment. In parallel, cortical neurons were exposed
to HCA and cobalt chloride (10-500 µM). Similar
quantitative results were obtained independent of the viability assay used.
Glutathione levels. Total glutathione levels were measured
by the method of Tietze (1969) as described in Ratan et al. (1994b) with the following modifications. At 0, 6, 9, and 12 hr after exposure
to potential toxins ± inhibitors, the cells were washed with PBS,
lysed with cold 3% perchloric acid, and centrifuged at 4°C at
7400 × g. The supernatants were diluted with 9 vol
of 0.1 M
Na2HPO4, and the remaining
steps of the glutathione assay were performed as described (Ratan et
al., 1994b). Glutathione levels were normalized to total protein levels
that were determined using the bicinchoninic acid reagent (Pierce,
Rockford, IL) method (Smith et al., 1985).
Immunoblot analysis. Cell lysates were obtained by rinsing
cortical neurons with cold PBS and adding 0.1 M potassium
phosphate containing 0.5% Triton X-100. Protein (2.5 µg) from cell
lysates was boiled in Laemmli buffer and electrophoresed under reducing conditions on 12% polyacrylamide gels. Proteins were then transferred to a polyvinylidene difluoride membrane (Bio-Rad, Hercules, CA). Nonspecific binding was inhibited by incubation in Tris-buffered saline
with Tween 20 (TBST; 50 mM Tris-HCl, pH 8.0, 0.9% NaCl, and 0.1% Tween 20) containing 5% nonfat dried milk for 1.5 hr. Primary antibodies against LDH (rabbit muscle; Rockland, Gilbertsville, PA), aldolase (rabbit muscle; Rockland), -tubulin (Sigma), HIF-1 (Novus Biologicals, Littleton, CO), or HIF-1 (Affinity Bioreagents, Golden, CO) were diluted 1:1000, 1:1000, and 1:2000 in TBST
containing 1% milk and exposed to membranes overnight at 4°C. For
LDH and aldolase, membranes were incubated with HRP-conjugated
anti-goat secondary antibody (Sigma), diluted 1:5000 in TBST containing 1% milk for 1.5 hr at room temperature. For the -tubulin
immunoblot, the membrane was incubated with HRP-conjugated anti-rabbit
secondary antibody (Amersham, Arlington Heights, IL), diluted 1:5000 in TBST for 1.5 hr at room temperature. Immunoreactive proteins were detected according to the enhanced chemiluminescent protocol (Amersham).
Immunofluorescence staining and confocal microscopy.
Indirect labeling methods were used to determine the levels of
HIF-1, HIF-1, and neurofilament (NF; 200 kDa) in cortical
neuronal cultures. Dissociated cells from the cerebral cortex
(3-5 × 105) were seeded onto
poly-D-lysine-coated eight-well culture slides (Becton
Dickinson, Bedford, MA) and treated with 100 µM DFO ± HCA as described above for 4-5 hr. The cells were washed with warm
PBS and fixed at room temperature for 15 min with 4% paraformaldehyde. After washing with PBS, fixed cells were incubated with blocking solution containing 0.3% Triton X-100, 5% bovine serum
albumin, and 3% goat serum for 1 hr, followed by incubation
with mouse anti-HIF-1 monoclonal antibody (1:200 dilution), rabbit
anti-HIF-1 polyclonal antibody (1:200-1000), or a mouse
anti-neurofilament antibody (1:100) overnight at 4° C. After three
washes with PBS, the cells were incubated for 1 hr with FITC-conjugated
goat anti-rabbit IgG antibody (1:200 dilution) and Texas
Red-conjugated goat anti-mouse IgG antibody (1:200 dilution; Vector
Laboratories, Burlingame, CA) or vice versa. All antibodies were
diluted in PBS. The slides were washed three times with PBS and mounted
with fluorochrome mounting solution (Vector Laboratories). Images were
analyzed using a confocal microscope (MRC-1024; Bio-Rad). Control
experiments were performed in the absence of primary antibody.
Aldolase activity. After 8 and 24 hr of exposure to the
HCA ± antioxidants ± protein synthesis inhibitors, cells
were washed with cold PBS and lysed with 0.5% Triton X-100 in 0.1 M potassium phosphate buffer, pH 7.0. The lysates were
divided for measurements of LDH activity (Ratan et al., 1994b),
aldolase activity (catalog #752-A; Sigma), and protein. The aldolase
assay is based on the spectrophotometric determination ( = 550 nm) of the levels of hydrazone formed when 2,4-dinitrophenylhydrazine
(a chromagen) is reacted with a hydrolysis product of dihydroxyacetone
phosphate. Dihydroxyacetone phosphate is formed from fructose
1,6-diphosphate in a reaction catalyzed by aldolase, and thus the
quantity of hydrazone is proportional to aldolase activity. The kit we
used was designed for use in serum; its sensitivity and specificity for
use in lysates of primary cultures were validated by use of serial
dilutions of a standard concentration of aldolase as well as by
addition of known quantities of aldolase to control lysates. Aldolase
activity is expressed as absolute absorbance values normalized to total protein.
Electrophoretic mobility shift assays and supershift
analysis. We performed electrophoretic mobility shift assays
(EMSAs) on nuclear extracts from cortical neurons using a
32P-labeled oligonucleotide containing a
wild-type (W18) or mutant (M18) HIF-1-binding site (Wang and Semenza,
1995). The sense strand sequences of the double-stranded W18 and M18
oligonucleotides are 5'-GCCCTACGTGCTGTCTCA-3' and
5'-GCCCTAAAAGCTGTCTCA-3', respectively. Parallel EMSAs were performed
using a radiolabeled Oct-1 (5'-TGTCGAATGCAAATGACTAGAA-3'; Santa Cruz
Biotechnology, Santa Cruz, CA)-binding site. Embryonic cortical
neurons were lightly trypsinized, pelleted, and resuspended in cold
PBS. All subsequent steps were performed as described previously at
4°C (Lin et al., 1995). The cells were suspended in 10 mM Tris, pH 7.5, 1.5 mM
MgCl2, 10 mM KCl, 10 µg/ml
aprotinin, 0.5 µg/ml leupeptin, 3 mM PMSF, 3 mM DTT, and 1 mM
Na3VO4 and lysed by 15 strokes in a Dounce homogenizer using a type B pestle, and the nuclei
were pelleted at 4500 × g for 5 min, resuspended in
3-4 packed cell vol of buffer C (420 mM KCl, 20 mM Tris-HCl, pH 7.8, 1.5 mM
MgCl2, 10 µg/ml aprotinin, 0.5 µg/ml
leupeptin, 3 mM PMSF, 3 mM
DTT, and 1 mM
Na3VO4), and incubated for
30 min with gentle agitation. The absence of cytoplasmic contamination of the purified nuclei was verified by the absence of detectable LDH
activity in the nuclear extract. The nuclear extract was centrifuged at
10,000 × g for 30 min, and the supernatant was
dialyzed twice against 25-50 ml of buffer D (20 mM Tris-HCl, pH 7.8, 100 mM
KCl, 0.2 mM EDTA, and 20% glycerol). The
dialysate was centrifuged at 10,000 × g for 10 min at
4°C, and the supernatants were aliquoted, snap frozen in liquid
N2, and stored at  80°C. Perchloric
acid-precipitated protein was measured from a representative aliquot
of each sample, and equal amounts were used for binding. Binding
reactions were performed at 4°C for 15 min using 3-15 µg of
nuclear protein (HIF-1 or Oct-1) and 0.25 ng (10,000-40,000 cpm) of
labeled oligonucleotide in 30 µl of binding buffer containing 10 mM Tris-HCl, pH 7.5, 50 mM
NaCl, 50 mM KCl, 1 mM
MgCl2, 1 mM EDTA, 5 mM DTT,
5% glycerol, and 0.1 µg of sonicated denatured calf thymus DNA. For
HIF-1 DNA-binding studies, a 10-fold excess of unlabeled M18 HIF-1
oligonucleotide was included in the binding reaction. DNA-protein
complexes were separated from unbound probe on native 6%
polyacrylamide gels at 195 V for 2 hr. The gel was vacuum dried and
exposed to Kodak film (Eastman Kodak, Rochester, NY) for 8-15 hr at
80°C. Visual inspection of the free probe band at the bottom of the
gel confirmed that equivalent amounts of radiolabeled probe were used
for each sample (data not shown). Supershifts were performed with
antibodies to HIF-1 (Wang et al., 1995a), HIF-1 (MA1-515;
Affinity Bioreagents), ATF-1/cAMP response element-binding
protein (CREB) (25C10G; Santa Cruz Biotechnology), or CREB-1 (24H4B;
Santa Cruz Biotechnology). The antibody was added to the binding
mixture immediately after the addition of the radiolabeled HIF-1 probe.
The reaction mixture was incubated for 20 min, and the complexes were
resolved as described above.
Northern blot analysis. Cells (2.5 × 106) derived from E17 cortices were
plated in six-well dishes. After 1-2 d in culture, the cells were
treated with or without iron chelators (± homocysteate). After a 4-6
hr exposure, total RNA was extracted from each treatment group using a
kit (RNAeasy; Qiagen, Valencia, CA). For each sample, 5 µg of total
RNA was electrophoresed in a 1% agarose and formaldehyde gel,
transferred to a positively charged nylon membrane, and hybridized with
enolase-1 (Semenza et al., 1996), LDH A (Semenza et al., 1996),
erythropoietin (Wang and Semenza, 1996; Juul et al., 1998), p21/waf1/cip1 (Carmeliet et al., 1998), and brain-derived neurotrophic factor (Masonpierre et al., 1990) cDNA probes. -actin was used as a
negative control (Marquis and Demple, 1998). After washing, the blots
were autoradiographed, and the bands were quantitatively analyzed using
a phosphorimager (GS-525 Molecular Image Analyzer; Bio-Rad).
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RESULTS |
Iron chelators inhibit glutathione depletion-induced apoptosis in
embryonic cortical neurons
In previous studies, we demonstrated that exposure of immature
cortical neurons to glutamate or the glutamate analog HCA
results in depletion of the antioxidant glutathione and in oxidative
stress-induced cell death with the morphological and biochemical
characteristics of apoptosis (Ratan et al., 1994a,b). To determine
whether iron participates in glutathione depletion-induced apoptosis,
we examined the protective effects of the iron chelator DFO in this
paradigm. At concentrations  10 µM, DFO completely
inhibited glutathione depletion-induced death. Concentrations of DFO
100 µM significantly inhibited not only the HCA-induced
death but also the small and reproducible level of cell death seen in
control cultures (Fig. 1A). The ability of DFO
to suppress the chromatin condensation and nuclear fragmentation
characteristic of apoptosis in both HCA-treated and control cultures
was verified by Hoechst 33258 staining (data not shown) and
phase-contrast microscopy (Fig. 2). MIM,
an iron chelator structurally distinct from DFO, also prevented
glutathione depletion-induced death in cortical neurons (Fig.
1B).
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Figure 1.
Effect of deferoxamine and mimosine on survival of
cultured cortical neurons treated with homocysteate. A,
Cultures were exposed to 1 mM HCA as described in Materials
and Methods with varying concentrations of DFO. The cells were
harvested at 24 hr and processed for LDH activity. Data are means ± SEM (expressed as a percentage of the total LDH activity in the
culture released into the medium) from three to five experiments
performed in triplicate. B, Effect of MIM on LDH release
in cultures exposed to 1 mM HCA for 24 hr is shown.
*p < 0.05 by ANOVA. CON,
Control.
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Figure 2.
Phase-contrast microscopy of primary cortical
neurons cultured for 2 d. A, Control (2 d in
vitro). B, Cells 24 hr after 1 mM
HCA to induce glutathione depletion. Arrowheads indicate
cells with morphological features characteristic of apoptosis: nuclear
and cytoplasmic condensation and phase-bright clumping of nuclear
chromatin. C, Cells exposed to 1 mM HCA and
100 µM DFO. Magnification, 200×.
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DFO acts distal to glutathione depletion in preventing
cell death
HCA induces glutathione depletion by competitively inhibiting the
uptake of cystine by its plasma membrane transporter (Murphy et al.,
1989, 1990). Inhibition of cystine uptake or removal of cystine from
the bathing medium leads to depletion of the antioxidant glutathione
and death because of oxidative stress. To determine whether iron
chelators act to suppress HCA-induced death by preventing cystine
deprivation and glutathione depletion, we measured total glutathione
levels [reduced glutathione (GSH) + oxidized glutathione (GSSG)] at
several time points after HCA addition (Fig.
3). Although the rate at which total
glutathione levels are depleted by HCA exposure is slowed in the
presence of 100 µM DFO, total glutathione levels are
depleted by >65% by 10 hr after treatment with HCA alone or HCA and
DFO in cortical neurons (Fig. 3). In contrast, there is little
difference between the total glutathione levels in control and
DFO-treated cultures, and levels remain unchanged throughout the 10 hr
period of observation (Fig. 3). These results suggest that iron
chelators act to inhibit glutathione depletion-induced apoptosis in
cortical neurons distal to glutathione depletion. Consistent with this
notion, both DFO and MIM could be added to cultures up to 10 hr after
HCA addition (4-7 hr after glutathione depletion) and completely
prevent cell death (data not shown).
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Figure 3.
Protection by iron chelators occurs distal to
glutathione depletion in the HCA-induced cell death pathway. Total
glutathione (nanograms of GSSG + GSH) per microgram of protein was
measured in cells exposed for 0, 6, or 10 hr to HCA, DFO, or both.
Values represent means ± SEM based on three to five experiments
performed in triplicate.
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Iron chelators induce several hypoxia response element-binding
activities in cortical neuronal cultures
To determine whether iron chelators can induce enhanced HIF-1 DNA
binding in cortical neuronal cultures, we performed EMSAs on nuclear
extracts from control and HCA-treated cells in the presence or absence
of DFO using a radiolabeled W18 oligonucleotide containing an HIF-1
DNA-binding site. Four hours of DFO treatment (100 µM)
significantly increased three DNA-binding activities in cortical
neurons in the presence or absence of HCA (Fig.
4A, the three DNA
binding activities are designated a, b, c). The induction of these DNA-binding activities by DFO seemed to be related
to iron chelation because it also occurred in the presence of the
structurally distinct iron chelator MIM (100 µM) (Fig. 4B). All three
DNA-binding activities were inhibited in a concentration-dependent manner by cold W18 oligonucleotide, but only the fastest mobility complex was inhibited by M18 oligonucleotide containing mutations in
the HIF-1-binding site (data not shown). These results demonstrate that the two slower mobility complexes (Fig. 4, complexes
a, b) bind the HIF-1 site specifically, whereas
the fastest-migrating complex (Fig. 4, complex c)
represents nonspecific DNA binding. Enhanced binding to the HIF-1 DNA
recognition sequence can occur within 2 hr after DFO treatment,
permitting sufficient time for putative protective genes to be
expressed before the commitment point of cells to die (~12 hr after
HCA treatment).
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Figure 4.
DFO and MIM induce HIF-1 DNA binding in embryonic
cortical neurons. A, EMSA performed with 15 µg of
nuclear extracts from control (left lane)
and DFO (100 µM)-, DFO (100 µM) + HCA (1 mM)-, and HCA (1 mM)-treated cortical neurons,
using a 32P-labeled HIF-1-binding site oligonucleotide.
B, EMSA performed as described in A with
15 µg of nuclear extracts from control and MIM (100 µM)-treated cortical neurons. C,
Identification of HIF-1 in complex a.
Antibodies to HIF-1 or HIF-1 were added after the addition of
radiolabeled oligonucleotide to the nuclear-binding reaction as
described in Materials and Methods. Ab, Antibody.
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Identification of HIF-1 and ATF-1/CREB in nuclear extracts after
iron chelator treatment
To determine whether HIF-1 was present in either of the
DFO-induced DNA-protein complexes detected by EMSA, we used antibodies specific for the HIF-1 and HIF-1 subunits. Addition of individual subunit-specific antibodies during in vitro DNA binding
revealed that the HIF-1 and HIF-1 were present in the
slower-migrating complex (Fig. 4C). Addition of HIF-1
antibody disrupted complex formation, whereas HIF-1 antibody
resulted in a DNA-protein-antibody complex of retarded mobility (supershift).
In addition to HIF-1, a faster-migrating, specific complex b
(Fig. 4) was also induced by DFO. The electrophoretic mobility of complex b corresponds to a constitutive binding activity
in non-neuronal cells whose levels of binding are independent of oxygen
tension or iron chelation (Wang and Semenza, 1993). Analysis of HeLa
cells identified the constitutive binding activity to the HIF-1
recognition sequence as ATF-1 and CREB, which also bind to the cAMP
response element (CRE) (Kvietikova et al., 1995). The unexpected
induction of complex b in cortical neurons by iron chelators
suggested the possibility that it might have an identity distinct from
ATF-1 and CREB. To explore this possibility further, we performed a
competition experiment using increasing molar excesses of unlabeled CRE
oligonucleotide containing the consensus binding site for ATF-1 and
CREB. This oligonucleotide has been shown previously not to inhibit DNA
binding by HIF-1 (Kvietikova et al., 1995). Unlabeled CRE
oligonucleotide competitively inhibited the formation of complex
b at lower concentrations of oligonucleotide than were required to
inhibit HIF-1 DNA binding (data not shown), suggesting that
complex b might contain ATF-1 and CREB. An antibody that recognized both ATF-1 and CREB completely supershifted complex b, whereas a CREB-specific antibody partially supershifted the same complex (Fig. 5A).
Antibodies to HIF-1 and HIF-1 had no significant effect on this
complex (Fig. 4). These results suggest that, in E17 rat
embryonic cortical neurons, ATF-1 represents the primary ATF/CREB
family member that binds to the HIF-1 recognition sequence and
establish the identity of the two induced HIF-1 recognition sequence-binding activities as HIF-1 and ATF-1/CREB. The differences between nuclear HIF-1 and ATF-1/CREB activity in control and
DFO-treated cortical neurons could not be attributed to global
differences in nuclear proteins because levels of the transcription
factor Oct-1 were similar in these two extracts (Fig. 5B)
.
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Figure 5.
DFO induces ATF-1 and CREB DNA binding to the
HIF-1 recognition sequence in embryonic cortical neurons.
A, EMSAs were performed (see Fig. 4 for
description) using 100 µM DFO. Complex b
was identified as ATF-1 and CREB. Antibodies recognizing ATF-1 and CREB
or CREB alone were added to the binding reaction as described in
Materials and Methods; d corresponds to a
DNA-protein-antibody complex. HIF-1 is less apparent in this EMSA
because the gel was exposed for shorter periods of time than were other
gels (see Fig. 4A-C). fp
corresponds to free unbound radiolabeled probe; c
corresponds to nonspecific DNA-binding activity. B, The
effect of DFO on Oct-1 DNA-binding activity is shown. The EMSA of
nuclear extracts from control (left lane)
and DFO-treated cells using a radiolabeled oligonucleotide with a Oct-1
sequence is shown.
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EMSAs were performed to determine whether 10 µM DFO, the
lowest concentration of chelator required to prevent glutathione depletion-induced death (Fig. 1), could induce HIF-1 and/or ATF-1/CREB DNA-binding activity. Induction of both complexes was observed after 4 hr of treatment with 10 µM DFO, although higher levels of
induction of both complexes were seen at higher concentrations of drug
(data not shown). At the three concentrations of DFO tested, supershift
analysis confirmed that the induced complexes were composed of HIF-1
and ATF-1/CREB (Fig. 4C; data not shown). Thus, protection from glutathione depletion-induced death by iron chelators in cortical neuronal cultures can be correlated with induction of HIF-1
and ATF-1/CREB.
Iron chelators induce HIF-1 DNA-binding activity in neurons
The studies described above used primary cultures that are
85-90% neuronal but contain glial cells as well (Murphy et al., 1990). In these cultures, the induction of HIF-1 and ATF-1/CREB may
occur in neurons and/or glia. To determine whether HIF-1 and ATF-1/CREB
can be induced in cortical neurons by iron chelators, we used a
conditionally immortalized cell line (H19-7) derived from hippocampal
neuroblasts (Eves et al., 1996). After differentiation, these cells
express neuronal markers (neurofilament positive and glial fibrillary
acidic protein negative) (Eves et al., 1996). Treatment of
undifferentiated or differentiated H19-7 cells for 4 hr with 100 µM DFO resulted in induction of two specific complexes similar to those induced in embryonic cortical neurons (data not shown). Supershift analysis confirmed that the slower-migrating complex
was HIF-1 and the faster-migrating complex was ATF-1/CREB (data not
shown). To verify that HIF-1 expression can be induced in neurons in
response to iron chelator treatment, we performed immunohistochemical
staining with antibodies to HIF-1 (data not shown) and HIF-1
(Fig. 6) followed by confocal microscopy.
These experiments confirmed that HIF-1 is activated in both neurons (Fig. 6) and glia (data not shown).
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Figure 6.
DFO induces HIF-1 levels in neurons.
Immunocytochemical analysis of HIF-1 (a, d) and
neurofilament (b, e) in mock- (a-c) or
DFO-treated (d-f) mixed cortical neuronal
cultures. The images in c and
f are derived from superimposing the HIF-1 Ab
fluorescence on the NF Ab fluorescence.
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Iron chelators induce expression of HIF-regulated genes in cortical
neuronal cultures
To determine whether known HIF-1-regulated genes are induced by
iron chelators in cortical neuronal cultures, we exposed cultures to
increasing concentrations of DFO, and total RNA was isolated for blot
hybridization using cDNA probes for LDH A, enolase-1, p21waf1/cip1, or erythropoietin. LDH,
enolase, p21, and erythropoietin are known to be upregulated by hypoxia
via HIF-1 in non-neuronal cells. A -actin cDNA probe was used as a
control. Quantitation of LDH A mRNA revealed a concentration-dependent
induction by DFO in the presence or absence of HCA (Fig.
7A,B). The induction of LDH A
mRNA by HCA is unlikely to be mediated by HIF-1 because we did not
observe increases in HIF-1 DNA binding under these conditions (Fig.
4A). In addition to mRNA for LDH A, mRNAs for
enolase-1, p21waf1/cip1, and
erythropoietin were also induced in a concentration-dependent manner by
DFO (Fig. 7C), whereas expression of -actin (Fig. 7) and
BDNF mRNA (data not shown) was unchanged. Because brain erythropoietin is expressed primarily in glial cells (Masuda et al., 1994) and glial
cells represent <20% of the cells in our culture (Murphy et al.,
1990), it is not surprising that erythropoietin mRNA expression was induced to a lesser degree than was that of LDH A, enolase-1, or
p21waf1/cip1.
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Figure 7.
Effect of DFO exposure on gene expression.
A, Cortical neuronal cultures were exposed to 0, 10, 100, or 500 µM DFO for 6 hr, and total RNA was isolated
for blot hybridization with an LDH A cDNA probe. The blot was stripped
and reprobed with a -actin probe as a control. B,
Hybridization signals were quantified by phosphorimager analysis. The
graph shows the level of LDH A mRNA normalized to that of -actin.
C, Induction of p21waf1/cip1,
enolase-1, and erythropoietin mRNA expression by exposure of cells to
DFO (10, 100, and 500 µM) is shown. Each plot is a
representative example of three separate experiments.
|
|
Iron chelators induce glycolytic enzymes via a
transcriptional mechanism
Immunoblot assays revealed that 100 µM DFO increased
LDH and aldolase protein levels, whereas levels of -tubulin protein remained unchanged (data not shown). These results indicate that the
increased mRNA levels observed after DFO treatment lead to corresponding increases in protein levels. Spectrophotometric measurements confirmed that induction of LDH and aldolase protein levels by DFO is associated with increases in enzyme activity (data not
shown). To verify that the increases in activity we observed are the
result of transcriptional mechanisms, we examined the effects of the
protein synthesis inhibitor cycloheximide and the RNA synthesis
inhibitor actinomycin-D on the induction of glycolytic enzyme activity
by iron chelation. We used concentrations of cycloheximide (10 µg/ml)
and actinomycin-D (2 µg/ml) that are known to inhibit incorporation
of radiolabeled amino acids into protein by >90 and 60%,
respectively, in cortical neurons (Ratan et al., 1994b). Cycloheximide
and actinomycin-D almost completely inhibited the induction of LDH and
aldolase activity by iron chelators (data not shown). These results
suggest that iron chelators induce glycolytic enzyme activities via a
transcriptional mechanism in cortical neurons, although we cannot
exclude the possibility that actinomycin-D and cycloheximide attenuate
HIF-1-regulated gene expression by abrogating DFO-induced HIF-1
induction. The antioxidant butylated hydroxyanisole did not
induce LDH activity in cortical neurons at concentrations that prevent
HCA-induced apoptosis. This result indicates that induction of LDH
activity is not required for protection and that some (DFO and MIM) but
not all antioxidants induce glycolytic enzyme activity.
Cobalt chloride, an activator of HIF-1, prevents glutathione
depletion-induced death in cortical neurons
The results described above support the hypothesis that iron
chelators protect neurons, in part, by activating a hypoxia signal transduction pathway leading to activation of HIF-1 and/or ATF-1/CREB and their protective target genes and predict that other known activators of this pathway will prevent glutathione depletion-induced death in cortical neurons. Divalent cations such as cobalt chloride have been shown to induce HIF-1 DNA binding and expression of hypoxia-inducible genes (Wang and Semenza, 1993; Semenza et al., 1994).
We therefore examined the effects of cobalt chloride (10-500 µM) on HIF-1 activation and glutathione
depletion-induced death in cortical neurons. Concentrations of cobalt
chloride >200 µM significantly reduced glutathione
depletion-induced death (Fig. 8A). Zinc chloride
(>200 µM) was not protective, and addition of
2 mM calcium chloride did not reverse protection
by 250 µM cobalt chloride (data not shown).
These results suggest that the protective effects are independent of
cobalt's ability to block calcium influx. Moreover, similar to iron
chelators, protective concentrations of cobalt chloride also induced
HIF-1 (Fig. 8B) and HIF-1 (data not shown)
protein expression and ATF-1/CREB (data not shown) as well as lactate
dehydrogenase activity levels (Fig. 8C) in cortical
cultures.
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Figure 8.
Effects of cobalt chloride on HIF-1 levels, LDH
activity, and glutathione depletion-induced death. A,
Cell viability was measured in cortical neuronal cultures (as described
in Materials and Methods) 24 hr after HCA treatment and
coadministration of vehicle (CON),
CoCl2 (250 µM), or DFO (100 µM). *p < 0.05, different from
control by ANOVA. B, Whole-cell lysates were prepared
from cortical neurons treated for 5 hr with vehicle
(control), CaCl2 (250 µM), or DFO
(100 µM) treatment and subjected to immunoblot analysis
using antibodies against HIF-1 and -tubulin protein.
C, LDH activity from cell lysates was measured (as
described in Materials and Methods) 24 hr after control
(CON), CoCl2 (250 µM),
or DFO (100 µM) treatment. *p < 0.05 by ANOVA.
|
|
| |
DISCUSSION |
Protection from cell death by iron chelators has been widely
attributed to their ability to prevent hydroxyl radical formation from
the iron-catalyzed reaction of superoxide and hydrogen peroxide (the
Haber-Weiss reaction) (Winterbourn, 1995). However, recent studies
suggest additional mechanisms of protection by iron chelators (Beckman
et al., 1990; Farinelli and Greene, 1996; Park et al., 1997a,b, 1998).
In this manuscript, we present data supporting a novel mechanism by
which iron chelators abrogate cell death in neurons. We correlate the
protective effects of iron chelation with the induction of the
transcription factors HIF-1 and ATF-1/CREB and with the enhanced
expression of genes encoding glycolytic enzymes,
p21waf1/cip1, and erythropoietin. Each of
these genes has HIF-1- and ATF-1/CREB-binding sites in their
promoters (Wang and Semenza, 1993; Semenza et al., 1994, 1996). That
activation of HIF-1 and ATF-1/CREB may be causally linked to protection
by iron chelators is supported by the ability of cobalt chloride
(another activator of HIF-1 and ATF-1/CREB and their target genes in
neurons) to prevent glutathione depletion-induced death (Fig. 8). This
link is further strengthened because cobalt chloride, unlike DFO and
MIM, is not known to have direct antioxidant-scavenging capacity.
Several plausible schemes can be envisaged by which the induction of
HIF-1- and/or ATF-1/CREB-regulated genes, by exposure to iron
chelators (or cobalt chloride), might prevent oxidative stress-induced
death. Iron chelators may prevent oxidative stress-induced death by
inducing glycolytic enzyme gene expression and consequent aerobic
glycolysis. Indeed, recent studies have demonstrated that a shift in
energy generation from glucose oxidation in mitochondria to aerobic
glycolysis in proliferating thymocytes is associated with resistance to
oxidative stress (Brand, 1997). The decrease in ROS resulting
from aerobic glycolysis can be attributed to two cooperative effects:
(1) the generation of the antioxidant pyruvate and (2) the
prevention of excessive reactive oxygen species production by reducing
the rate of mitochondrial glucose oxidation (Boveris and Chance, 1973;
Dykens, 1997). The ability of chelators to stimulate aerobic glycolysis
is supported by studies in muscle cells, in which iron chelators have
been shown to increase glucose consumption, lactate production, and
[14C]glucose incorporation into glycogen
by approximately twofold, and these changes were associated with
increases in levels of glucose transporter (GLUT-1) protein and mRNA
concentration (Potashnik et al., 1995). Of note, the transcriptional
induction of GLUT-1 by iron chelators or hypoxia has been shown to
require the HIF-1 recognition site (Ebert et al., 1995), and
HIF-1-deficient embryonic stem cells express reduced levels of
mRNAs encoding 13 different glucose transporters and glycolytic
enzymes, including aldolase A, enolase-1, glut-1, and LDH A (Iyer et
al., 1998). These data indicate that the effects of chelators on
glucose metabolism were likely mediated, in part, via HIF-1. Thus, by
inducing glycolytic enzyme expression, iron chelators may reduce the
ambient free radical burden of neurons by enabling the cell to generate
more energy (and antioxidant capacity) glycolytically and minimize the
deleterious consequences of mitochondrial glucose oxidation (Tan et
al., 1998). Future studies will clarify whether iron chelators enhance
glucose use, pyruvate production, and lactate production in embryonic
cortical neurons and whether these changes can be associated with
reduced free radical production.
Other gene products regulated by HIF-1 that may mediate some of the
salutary effects of iron chelators in neurons include erythropoietin,
which has been shown to be synthesized in glial cells (Masuda et al.,
1994) and to prevent cell death of serum-deprived cholinergic (Konishi
et al., 1993) or ischemic hippocampal neurons (Sakanaka et al.,
1998); heme oxygenase-1 (Lee et al., 1996, 1997), which has been shown
to prevent ischemia-induced neuronal loss in the cortex (Takizawa et
al., 1998) and to enhance resistance of neuronal cells to -amyloid
and hydrogen peroxide (Le et al., 1999); and the cyclin-dependent
kinase inhibitor p21/Waf1/Cip1 (Carmeliet et al., 1998), whose
overexpression in sympathetic neurons protects these cells from death
induced by nerve growth factor deprivation (Park et al., 1997a,b, 1998;
Freeman, 1998). The observation that DFO induces p21/Waf1/Cip1 in
cortical neurons (Fig. 7C) suggests that iron
chelators may suppress cell death induced by growth factor deprivation,
in part, by upregulating HIF-1 and/or ATF-1/CREB, leading to an
induction of p21/Waf1/Cip1.
The hypothesis that iron chelators protect neurons from oxidative
stress by inducing HIF-1 and/or ATF-1/CREB predicts that maximal
suppression of free radical generation as well as maximal protection by
iron chelators requires new mRNA and protein synthesis. Because
inhibitors of RNA or protein synthesis can abrogate glutathione depletion-induced death (Ratan et al., 1994b; Esch et al., 1998), we
could not use these inhibitors to determine whether transcription is
required for the protective effects of iron chelators. Future studies
using dominant-negative constructs of HIF-1 (Forsythe et al., 1996;
Jiang et al., 1996) and ATF-1 or CREB (Ahn et al., 1998) will address
this question directly. Of note, recent studies have documented a
proapoptotic effect of HIF-1 in embryonic stem cells or cortical
neurons under conditions of hypoxia (Carmeliet et al., 1998; Halterman
et al., 1999). In this context, HIF-1 appears to mediate upregulation
of p53 and downregulation of Bcl-2 leading to cell death. Although our
data, along with previous studies (Iyer et al., 1998), suggest that
HIF-1 mediates prosurvival responses, these observations suggest that
the effect of HIF-1 induction may depend on the cell type, the
developmental stage of the cell, or the death stimulus.
Our results indicate that as in non-neuronal cells, treatment with iron
chelators induces HIF-1 activity and expression of HIF-1-regulated
genes (Wang and Semenza, 1993: Semenza et al., 1994; Melilo et al.,
1997). The precise mechanism by which iron chelators engage the hypoxia
signal transduction pathway and activate HIF-1 remains unclear (Gleadle
et al., 1995; Huang et al., 1995; Wang et al., 1995a,b). However, our
studies point out some important differences in the nature of the
DNA-binding complexes induced by chelators in neurons versus
non-neuronal cells. Specifically, in neurons, iron chelators induce the
binding of both HIF-1- and ATF-1/CREB-binding activities. These
observations raise the possibility that HIF-1 and ATF-1/CREB act
together at the HIF-1 recognition sequence or, alternatively, at
different DNA sites to regulate glycolytic gene expression in neurons.
Of note, recent studies suggest that the transcriptional activation of
the LDH A gene in response to hypoxia requires a multiprotein complex
that includes HIF-1, ATF-1/CREB, and the coactivator p300/CREB-binding
protein (Firth et al., 1995; Ebert and Bunn, 1998). It is unlikely that the induction of ATF-1/CREB in neurons but not in non-neuronal cells by
iron chelators can be attributed to the postmitotic state of these
cells, because the induction of HIF-1 and ATF-1/CREB was also
demonstrated in mitotic H19-7 hippocampal neuroblasts in response to
iron chelation.
In summary, we demonstrate that structurally distinct iron chelators
abrogate glutathione depletion-induced apoptosis in neurons by acting
distal to glutathione depletion. We correlate the protective effects of
chelators with their ability to induce the transcription factors HIF-1
and ATF-1/CREB and the upregulation of glycolytic enzymes,
p21waf1/cip1, and erythropoietin. These
observations suggest that the induction of genes known to compensate
for hypoxic stress may mediate the neuroprotective effects of iron
chelators (and cobalt chloride) and identify novel potential
applications for iron chelators (and cobalt chloride) in the treatment
of neurodegenerative diseases associated with oxidative stress or
disrupted energy metabolism (Beal, 1996; Sharp et al., 1998).
| |
FOOTNOTES |
Received June 24, 1999; revised Aug. 12, 1999; accepted Sept. 1, 1999.
This work was supported by the National Institutes of Health Grants K08
NS01951, R29 NS34943, and R01 NS39170 to R.R. and a William Randolph
Hearst Fund award to R.R. We would like to thank Bruce Demple and Ed
Monuki for helpful suggestions on this manuscript, Shu-Hua Gu for
expert technical assistance, Bert Vogelstein for the p21/waf1/cip1
cDNA, Rosalind Segal for the BDNF cDNA, and Eva Eves for the H19-7 cell line.
Correspondence should be addressed to Dr. Rajiv R. Ratan, Neurology
Labs at The Beth Israel Deaconess Medical Center, Harvard Institutes of
Medicine, Room 857, 77 Avenue Louis Pasteur, Boston, MA 02115. E-mail:
rratan{at}caregroup.harvard.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
