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The Journal of Neuroscience, November 1, 1999, 19(21):9209-9217
Optical Imaging Reveals Elevated Intracellular Chloride in
Hippocampal Pyramidal Neurons after Oxidative Stress
Renu
Sah and
Rochelle D.
Schwartz-Bloom
Department of Pharmacology and Cancer Biology, Duke University
Medical Center, Durham, North Carolina 27710
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ABSTRACT |
The accumulation of reactive oxygen species (ROS) in the brain is
associated with several neurodegenerative conditions. ROS can affect
ionic homeostasis leading to impaired neurotransmission. Here, we
determined the ability of H2O2, a
membrane permeant ROS, to alter intraneuronal Cl ,
an important regulator of neuronal excitability. Real-time alterations in intracellular chloride, [Cl]i, were measured
with UV laser scanning confocal microscopy in hippocampal slices loaded
with the cell-permeant form of
6-methoxy-N-ethylquinolium iodide (MEQ), a
Cl-sensitive fluorescent probe. In slices
superfused with H2O2 for 10 min, there was a
significant decrease in MEQ fluorescence (elevation in
[Cl]i) in area CA1 pyramidal cell soma but not
in interneurons located in stratum radiatum. Alterations in
[Cl]i induced by H2O2
were prevented by the iron chelator deferoxamine and the vitamin E
analog Trolox, suggesting the involvement of free radicals. The influx
of Cl probably occurred through the GABA-gated
Cl channel because the effects of
H2O2 were blocked by picrotoxin. In addition,
HPLC analysis of the superfusates indicated that GABA and glutamate
accumulated extracellularly after H2O2
exposure. Excitatory amino acid receptor antagonists
2-amino-5-phoshopentanoic acid and 1,2,3,4-tetrahydro-6-nitro-2,
3-dioxo-benzo[f]quinoxaline-7-sulfonamide also attenuated the
effect of H2O2 on MEQ fluorescence. The changes in [Cl]i induced by H2O2
were Ca2+-dependent and
Na+-independent. After exposure of slices to
H2O2, the ability of the GABA agonist
muscimol to increase [Cl]i was attenuated. Thus,
ROS, like H2O2, may impair transmembrane Cl gradients and reduce inhibitory
neurotransmission, further promoting neuronal damage in oxidative
stress-related disease and in aging.
Key words:
oxidative stress; intracellular chloride; hippocampal
neurons; imaging; H2O2; GABA
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INTRODUCTION |
Reactive oxygen species (ROS) are
byproducts generated by cellular oxidative metabolism. However,
enhanced production of ROS, exceeding the intrinsic antioxidant
scavenging capacity, leads to the development of several
pathophysiological conditions. Brain tissue may be especially
vulnerable to ROS damage because of high oxygen consumption,
moderate antioxidant capacity, and membranes rich in easily oxidized
polyunsaturated lipids. Mounting evidence has implicated the role of
ROS in the pathophysiology of neurodegenerative conditions such as
Parkinson's disease, Huntington's disease, Alzheimer's disease, and
in normal aging (for review, see Beal, 1995 ; Simonian and Coyle, 1996).
An essential component of ROS-induced neurotoxicity may involve the
modulation of various ion transport proteins and receptor-gated ion
channels either directly via protein oxidation or indirectly via
peroxidation of membrane phospholipids (Kourie, 1998).
The effect of ROS on synaptic transmission has been examined previously
in the hippocampal slice. With exposure to oxygen free radicals,
synaptic efficacy and the ability to generate spikes are impaired
(Pellmar et al., 1989). EPSPs have been shown to be
reduced (Pellmar, 1995) or enhanced (Frantseva et al., 1998) in neurons exposed to ROS. However, IPSPs were significantly
reduced in both of these studies. Presynaptic and postsynaptic
mechanisms have been implicated in the alteration of synaptic function
by ROS (Colton et al., 1989; Pellmar, 1995), although specific targets have not been identified.
The sensitivity of inhibitory neurotransmission (i.e., GABAergic
neurotransmission) to oxidative stress may be particularly important
because a reduction in neuronal inhibition can lead to neuronal
excitability. Previously, we reported that the generation of superoxide
radicals in cerebral cortical synaptoneurosomes reduced
GABAA receptor activity (Schwartz et al., 1988).
In addition, we have demonstrated an increase in intracellular chloride
([Cl]i) and a subsequent
reduction in GABAA responses in hippocampal neurons after in vitro ischemia (oxygen-glucose
deprivation) (Inglefield and Schwartz-Bloom, 1998). Previous reports
indicate that alterations in GABAA
receptor-mediated inhibition may underlie hydrogen peroxide (H2O2)-induced changes in
synaptic transmission (Katsuki et al., 1997). However, little is known
about the effects of ROS on intracellular Cl levels and
GABAA receptor activity in an intact neuronal system.
Here, using optical imaging techniques and fluorescent dyes, we
investigated the ability of
H2O2, a membrane-permeant
ROS, to affect intracellular Cl in
hippocampal area CA1 pyramidal neurons and interneurons. Our working
hypothesis was that ROS can perturb transmembrane
Cl gradients within hippocampal neurons,
resulting in reduced GABAA responses. We observed
that exogenous H2O2 caused
a Ca2+-dependent increase in intracellular
Cl in area CA1 pyramidal neurons of the
hippocampus, followed by a reduction in GABAA
responses. We suggest that impairment of Cl gradients by
H2O2 could reduce
GABAA receptor-mediated inhibitory transmission
and promote neuronal damage in a variety of neurodegenerative conditions.
Part of this paper has been published previously in abstract form (Sah
and Schwartz-Bloom, 1999).
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MATERIALS AND METHODS |
Materials. 6-methoxy-N-ethylquinolium
iodide, (MEQ), carboxy-dichlorodihydrofluoresein diacetate
(c-H2DCFDA), and propidium iodide were purchased
from Molecular Probes (Eugene, OR). Trolox was obtained from Fluka
BioChemika (Ronkonkoma, NY).
D-2-amino-5-phosphopentanoic acid
(D-AP-5) was obtained from Tocris Cookson
(Ballwin, MO). Tiagabine and
1,2,3,4-tetrahydro-6-nitro-2,3-dioxo-benzo[f]quinoxaline-7-sulfonamide (NBQX) were a gift from Novo Nordisk (MålØv, Denmark). All other drugs were purchased from Sigma (St. Louis, MO).
Preparation of dihydro-MEQ. For loading hippocampal slices,
MEQ was reduced to its cell-permeable derivative,
6-methoxy-N-ethyl-1,2-dihydroquinoline (dihydro-MEQ) as
described previously by our laboratory (Inglefield and Schwartz-Bloom,
1997). Briefly, reduction was performed by gradual addition of sodium
borohydride (12% in H2O, 32 µM) to an aqueous solution of MEQ (16 µM) under nitrogen for 30 min. Formation of the
dihydro derivative was accompanied by the appearance of a
reddish-yellow oil that was extracted twice with ethyl acetate (0.5 ml). Organic extracts were combined and dried with anhydrous MgSO4, and the ethyl acetate was evaporated under
N2 in a glass microvial. Reduced dye was stored
at  80°C under N2 and used within 2-3 d for
optimal loading of brain slices.
Hippocampal slice preparation and bath loading of
dihydro-MEQ. Transverse hippocampal slices (300 µm) were
prepared from 12- to 19-d-old Sprague Dawley rats (Charles River
Laboratories, Wilmington, MA) using a vibratome in ice-cold oxygenated
(95% O2-5% CO2 mixture) physiological Ringer's buffer. Composition of the Ringer's buffer consisted of (in mM): 119 NaCl, 2.5 KCl, 1.0 NaH2PO4, 1.3 MgCl2, 2.5 CaCl2, 26 NaHCO3, and 11 glucose, pH 7.4. The
osmolality of this buffer was 285-290 mOsm/l. For low
Ca2+ or
Na+-containing buffers, appropriate
iso-osmotic ion equivalents were added to account for osmolality and pH
changes caused by removal of ions. Slices were transferred to a nylon
net submerged in oxygenated Ringer's buffer (room temperature) and
allowed to equilibrate for at least 0.5-1 hr before dye loading. Bath
loading of slices with resuspended dihydro-MEQ (final concentration of
~400 µM) was carried out at room temperature
for 30 min in Ringer's buffer. The slices were washed once in fresh
oxygenated Ringer's to remove extracellular dye before transfer to the
imaging chamber. Intracellularly trapped MEQ has high
Cl sensitivity, low toxicity, and a slow
leakage rate (Biwersi and Verkman, 1991). Because the fluorescence of
MEQ is quenched collisionally by Cl,
fluorescence intensity is inversely related to
[Cl]i.
UV laser scanning confocal microscopy. The use of UV laser
scanning confocal microscopy to measure
Cl-sensitive changes in MEQ fluorescence
in hippocampal slices has been described previously by our laboratory
(Inglefield and Schwartz-Bloom, 1997). After loading with MEQ, slices
were submerged in a chamber that was superfused with oxygenated
Ringer's buffer (flow rate of ~1.5 ml/min) at room temperature. For
all experiments, slices were allowed to equilibrate in the chamber for
at least 10-15 min before the baseline recording period. The imaging
chamber was positioned on the stage of an upright Nikon (Tokyo, Japan) Optiphot microscope. The laser scanning confocal microscope (Noran Odyssey; Noran Instruments, Middleton, WI) was equipped with an argon
ion UV laser (50 mW output; Enterprise 653; Coherent-AMT, Kitchener,
Ontario, Canada) and a digital imaging system using Image-1 software
(Universal Imaging Corporation, West Chester, PA) for image and data
acquisition. MEQ-loaded neurons were imaged by excitation with the 364 nm line of the UV laser (attenuated to 18% intensity using the
acousto-optical modulator of this system). Fluorescent light was
transmitted through a UV water-immersible objective (40× NA; Olympus
Optical, Tokyo, Japan). Emission (Emmax of 440 nm) was imaged using a 400 nm barrier filter. Photomultipliers detected
the fluorescent signal through a confocal slit at 1× electronic zoom
(unless otherwise noted). The video frame rates (32 images per second)
of the Noran Odyssey confocal microscope allowed rapid full-image
(512 × 480 pixels) acquisition. To minimize photobleaching of the
dye, repeated long-term illumination by the UV laser was limited.
Previously, we have characterized the kinetics of
photobleaching of MEQ to have a half-life
(t1/2) of 173.8 sec (Inglefield and
Schwartz-Bloom, 1997). Optical recordings totaling 1 sec of laser
illumination were made every 2-5 min, ensuring total laser
illumination of no more than 15 sec/slice. Images were 8-bit (256 intensity levels) and were recorded to a Panasonic (Secaucus, NJ)
optical memory disk recorder (model LQ-3031) for off-line analysis.
Before switching to H2O2 or
drug-containing buffer, a minimum of 5 min of baseline was recorded to
allow determination of the stable fluorescence of the cells.
When inhibitors were used, they were superfused during the
equilibration period (10-15 min) to ensure penetration within the slice.
Calibration of MEQ fluorescence sensitivity. Because MEQ is
not a ratioable dye, absolute [Cl]i
concentrations were not measured. However, changes in MEQ fluorescence can be calibrated to estimate changes in intracellular
[Cl] using the Stern-Volmer
relationship,
F0/FCl = 1 + Kq[Cl], where F0 is the total quenchable signal,
FCl is the fluorescence in the
presence of a given Cl concentration,
and Kq is the Stern-Volmer quench constant (in M1) (Verkman, 1990).
Previously, we have calibrated changes in MEQ fluorescence with
intracellular Cl under different
experimental conditions (Inglefield and Schwartz-Bloom, 1997, 1998).
For the imaging conditions described here, we determined the
Stern-Volmer constant (Kq) to be 16 ± 1 M1. The
Kq1 equals 61 mM, the Cl
concentration to quench MEQ fluorescence by 50%.
Propidium iodide fluorescence imaging. In certain
experiments, MEQ-loaded slices were superfused in the imaging chamber
with propidium iodide (PI) (2 µg/ml) for 5 min before imaging.
Propridium iodide was maintained in the buffer throughout the
experiment to prevent washout from the extracellular space. Healthy
cells are impermeable to PI. However, it enters neurons with damaged plasma membranes and fluoresces upon binding to nucleic acids. Detection of PI-positive neurons (indicating damaged plasma membranes) was achieved with a 488 nm excitation line and a 550 nm barrier filter.
Carboxy-dichlorofluorescein fluorescence imaging. To
monitor the accumulation of intracellular peroxides, separate slices (non-MEQ-loaded) were loaded with the nonfluorescent dye
c-H2DCFDA (10 µM) for 30 min at 30° C. This dye is freely permeable to cells, and it becomes
trapped inside after hydrolysis to
carboxy-dichlorodihydrofluorescein. Upon oxidation by
intracellular oxidants, primarily peroxides, it forms fluorescent
carboxy-dichlorofluorescein (c-DCF) (LeBel et al., 1992). Increases in
c-DCF fluorescence dependent on intracellular oxidant status were
measured using the 488 nm excitation line and a 515 nm barrier filter.
Laser illumination was limited to 1 sec exposures at 5 min intervals
for 15 min, and images were acquired using 16 frame averaging to
minimize photo-oxidation of this dye. Control slices were exposed to
H2O2-free Ringer's under
identical conditions.
Data analysis. Only those cells that had <10% change in
MEQ fluorescence during the initial baseline recording period and an
initial fluorescence intensity between 90-200 optical density units
were used for data analysis. Fluorescence intensity (optical density
arbitrary units) was measured over a central area of 5-10 morphologically distinct somata per slice within the imaged field. Within each frame, the average fluorescence intensity, F,
for either MEQ or c-DCF fluorescence was calculated and recorded. The
percent change in fluorescence from baseline for each cell ( F) was calculated by the equation
F = (Fb F/Fb) × 100, where Fb was basal fluorescence defined by
the three frames preceding the experimental recordings. Thus, each cell
served as its own control. There was a gradual rundown (baseline drift)
of MEQ fluorescence (9.9 ± 2% over 20 min) in control slices
primarily because of slow leakage of the dye. Thus, changes in MEQ
fluorescence induced by
H2O2 were always compared
with the fluorescence in slices not exposed to
H2O2 under similar
conditions (controls). Typically, we obtained data from three to four
stable cells per slice, from at least two slices per experiment,
repeated at least three times.
Measurement of amino acid overflow. To quantify the amounts
of GABA and glutamate released from the hippocampal slices, 100 µl of
the superfusate was collected from slices exposed to
H2O2 for 2 and 10 min.
Superfusates were sampled from control slices at the same time points.
Samples were stored at 20°C until analysis. Neurotransmitter amino
acids in the superfusates were derivitized with
o-phthalaldehyde and assayed by HPLC on a C18
reversed-phase column (4.6 × 80 mm; particle size, 3 µm;
Zorbax; Hewlett-Packard Co., Newport, DE) using 700 nM cysteic acid as the internal standard (Lindroth and Mopper, 1979; Peterson et al., 1995). The limit of
sensitivity was ~50 fmol.
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RESULTS |
H2O2- induced changes in
intracellular Cl
Freshly prepared hippocampal slices loaded with MEQ exhibited
numerous fluorescent neurons with a uniform dye distribution in area
CA1 stratum pyramidale (Fig.
1A). Dendrites of
several neurons were clearly visible depending on the optical plane of focus. In hippocampal slices exposed to
H2O2 (300 µM; 0.001%), MEQ fluorescence decreased
gradually in the cell soma of area CA1 stratum pyramidale (Fig. 1),
indicating an accumulation of intracellular
Cl. When
H2O2 was removed from the
superfusion buffer after 10 min, no additional decrease in MEQ
fluorescence was observed over the next 25 min (data not shown). Ten
minutes after exposure to
H2O2, MEQ fluorescence
decreased by 32 ± 2% compared with a 9.9 ± 0.8% decrease
in control slices over the same time period (also see Fig. 5).
According to the Stern-Volmer relationship (see Materials and
Methods), the decrease in MEQ fluorescence produced by 10 min
H2O2 exposure (corrected
for baseline drift) corresponds to an increase in intracellular
Cl of ~27 mM
(resting [Cl]i typically ranges
between 4 and 9 mM for neurons). The change in
MEQ fluorescence produced by
H2O2 in pyramidal neurons
was concentration-dependent (Fig. 2). No
change in MEQ fluorescence was observed below a concentration of 30 µM
H2O2 compared with control
cells. However, a significant reduction in MEQ fluorescence was
observed at concentrations  100 µM of
H2O2, and a maximal response was observed at 300 µM
H2O2. Applying higher
concentrations in the millimolar range produced no further decrease in
MEQ fluorescence. We did not test concentrations above 10 mM because these concentrations have been
reported to produce primary cytoplasmic and plasma membrane damage and
rapid necrosis (Gardner et al., 1997). Unless noted otherwise, all
experiments were performed with 300 µM
H2O2.
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Figure 1.
Effect of H2O2 on
intracellular MEQ fluorescence in area CA1 pyramidal cells.
A, Video confocal images of MEQ fluorescence before
(Control) and 10 min after
H2O2 (300 µM). The decreased
fluorescence in the bottom indicates an increase
in [Cl]i. Scale bar, 20 µm. B,
Time course for the H2O2-induced changes
in MEQ fluorescence within individual pyramidal cells. After
baseline recordings, hippocampal slices were superfused with 300 µM H2O2 ( ). The slow rundown
(baseline drift) for control cells is also shown ( ). Data are
mean ± SEM values of 8-14 cells for control and
H2O2 (4 slices per condition) from three
separate experiments. *p < 0.05 versus baseline
fluorescence; repeated-measures ANOVA followed by Tukey's post
hoc analysis.
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Figure 2.
Concentration-dependent decrease in MEQ
fluorescence by H2O2. MEQ-loaded slices were
exposed to increasing concentrations of H2O2.
The change in MEQ fluorescence (F) was
calculated as percent of baseline fluorescence for individual cells
after 10 min of H2O2. Data are from 6-25 cells
from at least three slices per condition. *p < 0.05 versus control; ANOVA and Tukey's post hoc
analysis.
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In contrast to pyramidal neurons, interneurons in area CA1 stratum
radiatum were resistant to
H2O2-induced changes in MEQ fluorescence (Fig. 3A). Ten
minutes after H2O2
exposure, there was no decrease in MEQ fluorescence compared with
controls (Fig. 3B). These findings are consistent with the
reported differences in vulnerability of area CA1 interneurons versus
pyramidal neurons after ischemic insults in vivo (Crain et
al., 1988; Inglefield et al., 1997).
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Figure 3.
Effect of H2O2 on
intracellular MEQ fluorescence in interneurons located in area CA1
stratum radiatum. A, Video confocal images of MEQ
fluorescence in an area CA1 interneuron before and 10 min after 300 µM H2O2 superfusion. Scale bar,
20 µm. B, H2O2 (10 min
superfusion) causes no significant change in MEQ fluorescence in
interneurons. Control bar represents the baseline drift
(over 10 min) of MEQ fluorescence in cells exposed to Ringer's buffer
without H2O2, under identical
experimental conditions. Data are mean ± SEM of four to nine
cells from four to six slices.
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c-DCF fluorescence in neurons after
H2O2
To verify that 10 min superfusion lead to adequate penetration of
H2O2 within neurons, we
assessed intracellular accumulation of
H2O2 and other ROS in
neuronal cell soma of CA1 pyramidal neurons using the
oxidation-sensitive dye c-DCF. This dye has been used as a probe for
evaluating H2O2 and other
ROS, and therefore, it is an indicator of oxidative stress in
biological systems (LeBel et al., 1992; Crow, 1997). There was a
significant increase (53 ± 6.6%) in c-DCF fluorescence in area
CA1 pyramidal neurons exposed to 300 µM
H2O2 for 10 min (Fig.
4). In addition, intense c-DCF fluorescence, which was punctate in distribution, was observed in the
neuropil area in most slices. The punctate staining in the neuropil
most likely reflected ROS accumulation in both terminals and dendrites,
and it precluded observation of individual c-DCF-loaded interneurons.
Control slices loaded with c-DCF and exposed to similar periods of
laser illumination elicited minimal changes in c-DCF fluorescence
during the experimental period (6.3 ± 2.2%), indicating
negligible laser-induced auto-oxidation and photoconversion of the dye
(Fig. 4B). The increase in c-DCF fluorescence was
more rapid in some neurons, which showed significant increases in c-DCF fluorescence by 5 min of
H2O2 superfusion (data not
shown). The variability could be related to the intracellular
H2O2 antioxidant status of
individual neurons.
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Figure 4.
Increased c-DCF fluorescence in cells after 10 min
H2O2, indicating elevation of ROS.
A, Confocal video images of c-DCF fluorescence in area
CA1 pyramidal cell soma before (Control) and
after H2O2 superfusion. Scale bar, 20 µm.
B, Changes in c-DCF fluorescence after 10 min
H2O2. Control bar represents the
baseline drift of c-DCF fluorescence in cells not exposed to
H2O2 under identical experimental conditions.
Data are mean ± SEM values of 12-22 cells from three to five
slices. *p < 0.05 versus control; Student's
t test.
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H2O2 effects are mediated via
free radicals
Normally, H2O2 is
metabolized by glutathione peroxidase or catalase to water and a
disulfide, or water and O2, respectively. If the
antioxidant capacity is exceeded,
H2O2, along with free Fe2+, promotes the production of hydroxyl
radicals (OH·) via the Fenton reaction (Haber and Weiss, 1934), which
peroxidizes lipids and proteins. To determine whether free radical
generation was involved in the effect of
H2O2 on MEQ fluorescence,
slices were superfused with the iron chelator deferoxamine mesylate
(100 µM). Deferoxamine completely prevented the
H2O2-induced decrease in
MEQ fluorescence (Fig. 5). In addition,
superfusion of slices with Trolox (50 µM), a
water-soluble form of  -tocopherol (vitamin E), prevented the ability
of H2O2 to decrease MEQ
fluorescence (Fig. 5). Thus, the H2O2-induced effects on
[Cl]i were probably a result of free
radical generation, most likely hydroxyl radicals rather than
H2O2 itself.
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Figure 5.
Effect of Trolox (50 µM) and
deferoxamine mesylate (DFX; 100 µM) on
H2O2-induced decreases in MEQ fluorescence.
Hippocampal slices were superfused with 300 µM
H2O2 for 10 min. The compounds were added 15 min before the addition of H2O2. Data are
mean ± SEM values of 10-24 cells from at least three slices per
condition. * p < 0.05 versus control; ANOVA
followed by Tukey's test.
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Propidium iodide fluorescence in MEQ-loaded cells after
H2O2
Free radicals, primarily OH·, can lead to peroxidation of
membrane phospholipids, resulting in a loss of membrane integrity and
cell death (Mattson, 1998). To determine whether neurons exposed to
H2O2 maintained plasma
membrane integrity, the MEQ-loaded slices were also loaded with PI,
which is excluded from living cells with intact plasma membranes. As
the plasma membrane becomes permeable, PI enters; it is relatively
nonfluorescent until it binds to nuclear chromatin. Control cells
loaded with MEQ showed no PI fluorescence (Fig.
6A,B).
Furthermore, cells continued to exclude PI after superfusion with
H2O2 for 10 min (Fig.
6D) and showed a significant reduction in MEQ
fluorescence (Fig. 6C). Thus, the concentration of
H2O2 used (300 µM) does not appear to damage plasma membranes. At the end of the experiment, the slices were incubated in Ringer's buffer containing 70% methanol as a positive control to permeabilize the cell membranes. Two minutes after exposure to methanol, there was
intense nuclear staining of cells by PI (Fig. 6E),
accompanied by a loss of MEQ fluorescence caused by damaged cell
membranes (data not shown).
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Figure 6.
MEQ fluorescent cells within area CA1 pyramidal
cell layer exclude PI 10 min after H2O2.
An MEQ-loaded slice was constantly superfused with PI.
A, MEQ fluorescent neurons in area CA1 before
H2O2. B, Neurons in
A imaged with the rhodamine filter for PI.
C, MEQ fluorescent neurons 10 min after
H2O2. D, Neurons in
C imaged with the rhodamine filter for PI.
E, As a positive control, the slice was exposed to
methanol for 2 min to allow entry of PI into the same cells shown in
A-D. All images were at a 1.7× electronic zoom to
maintain registry between multiple laser lines. Scale bar, 20 µm.
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H2O2-induced changes in
[Cl]i are secondary to release of GABA and
activation of excitatory amino acid receptors by glutamate
Increases in intracellular Cl in
neurons may occur as a result of opening of ligand-gated
Cl channels, e.g.,
GABAA receptors, passive influx to accompany Na+, or an impairment of
Cl extrusion mechanisms
(Alvarez-Leefmans, 1990). We performed specific antagonist and ion
replacement experiments to determine potential mechanism(s) for the
H2O2-induced accumulation
of [Cl]i. Superfusion of the slices
with the noncompetitive GABAA receptor antagonist
picrotoxin (100 µM) prevented the decrease in MEQ
fluorescence of pyramidal cells produced by
H2O2 (Table
1), suggesting that Cl influx was probably secondary to GABA
release. Tetrodotoxin (2 µM) had no affect on the
H2O2-induced change in MEQ
fluorescence (Table 1), indicating a lack of involvement of
voltage-dependent Na+ channels in the
elevation of [Cl]i by
H2O2. To assess whether
GABA was released by H2O2,
we measured GABA levels in the superfusates after exposure of
hippocampal slices to H2O2
under identical conditions used for imaging (Fig. 7). Within 2 min of
H2O2 superfusion, there was
a significant increase in the levels of GABA in the superfusate. In
addition, glutamate levels increased by 2 min of
H2O2 superfusion, but the increase was variable and did not reach statistical significance. To
determine whether the
H2O2-induced increase in
[Cl ]i involved the activation of
excitatory amino acid (EAA) receptors, slices were incubated with
D-AP-5 (50 µM) or NBQX (5 µM),
selective antagonists of NMDA and AMPA receptors, respectively. Both
compounds significantly attenuated the effect of
H2O2 on MEQ fluorescence (Table 1), indicating that activation of EAA receptors by glutamate was
also a component in the cascade of
H2O2-mediated effects on intracellular Cl.
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Table 1.
H2O2-induced [Cl]i
elevation is prevented by the GABAA-Cl
channel blocker picrotoxin (PTX) and excitatory amino acid receptor
antagonists (AP-5 and NBQX)
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Figure 7.
H2O2 causes an increase of
amino acids (AA), glutamate (--), and GABA (--) in the
superfusate of hippocampal slices. Superfusates were collected at 0 (basal), 2, and 10 min after 300 µM
H2O2. Data are from a single experiment and
represent three separate experiments. Accumulation of GABA was
significantly above basal (p < 0.05) at 2 and 10 min (repeated measures ANOVA, followed by paired Student's
t test).
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Ca2+ ions mediate the
H2O2-induced elevation in
[Cl]i
Oxidative species can cause the release of GABA via a
Ca2+-dependent exocytotic process (Rego et
al., 1996) and via a Ca2+-independent,
Na+-dependent GABA carrier-mediated efflux
(Oliveira et al., 1994). To investigate whether the
H2O2-induced increase in
intracellular Cl required the presence
of Ca2+, we superfused slices in a
Ca2+-deficient Ringer's buffer containing
1 mM EGTA, before the addition of
H2O2. The removal of
extracellular Ca2 + markedly prevented the
decrease in MEQ fluorescence by
H2O2 (Fig. 8). Thus, the
ability of H2O2 to elevate
[Cl]i appears to be dependent on the
influx of Ca2+. To determine whether GABA
carrier-mediated efflux (i.e., carrier reversal) contributed to the
H2O2-induced increase in
intracellular Cl, we substituted
Na+ (from NaCl) in the superfusion buffer
with an equimolar concentration of choline chloride. The removal of
Na+ had no effect on the ability of
H2O2 to decrease MEQ
fluorescence (Fig. 8).
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Figure 8.
H2O2-induced
Cl influx is Ca2+-dependent and
Na+-independent. All ion-substituted buffers were
iso-osmotic with the control Ringer's buffer. The
Ca2+-deficient buffer also contained 1 mM EGTA. In the Na+-deficient buffer,
choline chloride replaced NaCl. Data are mean ± SEM of 4-27
cells from at least three slices per condition. *p < 0.05 versus control; ANOVA followed by Tukey's post
hoc test.
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H2O2 decreases
GABAA responses
To determine whether the
H2O2-induced elevation in
intracellular Cl could limit
GABAA responses in the hippocampal slice, slices were superfused with H2O2
for 10 min, and the H2O2
was removed. The slices were superfused subsequently with the
GABAA agonist muscimol (50 µM) for
10 min. At this time, the ability of muscimol to decrease MEQ
fluorescence was significantly attenuated (by 25%; p < 0.05) compared with control slices not exposed to
H2O2 (Fig.
9).
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Figure 9.
H2O2 attenuates the
ability of muscimol to increase intracellular Cl
in area CA1 pyramidal cells. The GABAA agonist muscimol (50 µM) was applied for 10 min to the chamber containing
control slices or slices previously exposed to 10 min
H2O2. The F is the change in
MEQ fluorescence after 10 min of exposure of control or peroxidized
slices to muscimol. The F for each cell was
calculated as described in Materials and Methods, except the
fluorescence intensity values before muscimol addition were used for
the Fb. Data are the mean ± SEM of
7-14 cells from at least three slices per condition.
*p < 0.05 versus control; Student's
t test.
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DISCUSSION |
In the present study, we used the
Cl-sensitive dye MEQ and laser scanning
confocal microscopy to assess alterations in intraneuronal Cl in the hippocampal slice after a mild
oxidative insult induced by
H2O2. The use of the brain
slice preparation, which maintains a relatively intact circuitry,
allowed us to image both pyramidal neurons and interneurons under
identical conditions. A brief exposure of slices to
H2O2 caused a significant
increase in [Cl]i in CA1 pyramidal cell soma. A
comparison of the effects of H2O2 on MEQ and c-DCF
fluorescence indicated that the increase in
[Cl]i occurred simultaneously with the
accumulation of H2O2 and
related ROS inside the cell soma. Normally, ambient levels of
H2O2 in neurons are low
because of its efficient destruction by glutathione peroxidase
(Halliwell and Gutteridge, 1989). However, micromolar concentrations
(~100 µM) of
H2O2 are found in brain
after ischemia-reperfusion injury as measured by microdialysis (Hyslop
et al., 1995). These micromolar concentrations can also be reached in
aged brain tissue (Sohal et al., 1994; Auerbach and Segal, 1997),
possibly because of an overproduction and/or reduced metabolism of
H2O2.
In contrast to the acute sensitivity of pyramidal neurons to
H2O2, interneurons located
in area CA1 stratum radiatum did not demonstrate an increase in
[Cl]i in response to
H2O2. Interestingly,
differences in vulnerability of neuronal types to neurodegenerative
processes have been observed in cerebral ischemia and in Huntington's
disease (Crain et al., 1988; Inglefield et al., 1997; Calabresi et al.,
1998). GABAergic interneurons in the hippocampus have been shown to
survive long-term after an episode of cerebral ischemia, although they
do suffer considerable damage (Nitsch et al., 1989; Inglefield et al.,
1997). The exact reason(s) for the differing responses to
H2O2 between these two cell
types is not clear at present. However, some possible explanations may
include the following: (1) different levels of intracellular
antioxidants, (2) heterogeneity in GABAA-mediated Cl currents, (3) different efficiencies
of Cl extrusion mechanisms, and (4) the
neuronal circuitry. Interestingly, different levels of superoxide
dismutase (SOD1 and SOD2 isoforms) have been reported in striatal
cholinergic interneurons versus projection neurons, the latter being
more susceptible to neurodegenerative processes (Yamada et al., 1995;
Medina et al., 1996). Also, differential vulnerability of CA1 and CA3
subfields to superoxide and hydroxyl radicals has been reported in
hippocampal slices (Wilde et al., 1997); this difference in
vulnerability was attributed primarily to different levels of
antioxidant enzymes and iron binding proteins between the two cell
populations. Differences between pyramidal neurons and interneurons may
also exist with respect to Cl channel
kinetics (Xiang et al., 1998) and GABAA receptor
subunit composition (Sperk et al., 1997). In addition,
differential responses to oxidative stress have been reported in
thalamic and cortical neurons based on neuronal circuitary in which
loss or preservation of certain pathways modified electrophysiological
responses to H2O2
(Frantseva et al., 1998). Future studies are required to fully
understand the heterogeneity in responsiveness between hippocampal pyramidal neurons and interneurons to
H2O2.
Alterations in [Cl]i induced by
H2O2 in pyramidal neurons
were prevented in the presence of the iron chelator deferoxamine, suggesting that H2O2
effects were probably mediated by hydroxyl radicals rather than
H2O2 itself. This is
consistent with previous reports in which the effects of
H2O2 on synaptic efficacy
were dependent on the presence of free iron in hippocampal slices
(Pellmar et al., 1989). The ability of the antioxidant Trolox to
prevent the increase in [Cl]i by
H2O2 also supports a role
of free radicals in the actions of
H2O2.
How does H2O2 produce
elevated intraneuronal Cl in pyramidal
cell soma? Significant reduction of
H2O2 action by the
GABA-gated Cl channel antagonist
picrotoxin indicates that accumulation of Cl probably occurred as a result of its
influx through the GABAA ionophore, secondary to
elevation of extracellular GABA levels. To support this, we found
increased levels of GABA in superfusates collected from
H2O2-exposed slices. Our
studies agree with previous studies in which oxygen free radicals
increased basal release of GABA in hippocampal slices and in cultured
chick retinal neurons (Rego et al., 1996; Saransaari and Oja, 1998).
However, the mechanism(s) by which
H2O2 alters intraneuronal
Cl is probably more complex because it
must also account for the dependence of
H2O2 action on glutamate
receptor activation and on extracellular
Ca2+. The ability of
H2O2 and other ROS to cause
glutamate accumulation has also been documented. For example, elevated
levels of excitatory amino acids have been reported in hippocampal
slices and neuronal cultures on exposure to free radicals because of
enhanced release (Pellegrini-Giampietro et al., 1988; Satoh et al.,
1998) or impaired uptake (Volterra et al., 1994; Berman and Hastings,
1997). Free radicals can enhance basal release of excitatory amino
acids in the presence or absence of extracellular
Ca2+ (Gilman et al., 1994; Rego et al.,
1996). In addition, enhancement of excitatory neurotransmission was
observed after H2O2 in
thalamocortical neurons, along with attenuated inhibitory transmission
(Frantseva et al., 1998).
There is significant evidence implicating impaired
Ca2+ homeostasis after oxidative insults
(Mattson, 1998). Recently, Li et al. (1998) have reported that
H2O2 increased the
Ca2+ channel currents in cloned neuronal
voltage-dependent Ca2+ channels expressed
in Xenopus oocytes. Elevated
[Ca2+]i after
H2O2 has also been reported
in synaptosomes (Tretter and Adam-Vizi, 1996). Interestingly, elevated
[Ca2+]i in response to glutamate
receptor activation has been shown to increase levels of ROS (Dugan et
al., 1995; Reynolds and Hastings, 1995; Bindokas et al., 1996).
A model that includes the hippocampal circuit may be proposed to
account for the mechanism(s) by which
H2O2 increases
intracellular Cl. After exposure to
H2O2, glutamate could
accumulate (via Ca2+-dependent release
and/or impaired uptake) at synapses with GABA interneurons, thereby
activating glutamate receptors and causing GABA release. This process
appears to be TTX-insensitive. Because the effects of
H2O2 were blocked by
glutamate receptor antagonists, Ca2+-dependent release or impaired uptake
of GABA at interneuron terminals appear to be insignificant. Thus,
glutamate terminals may be more sensitive to
H2O2 than are GABA
terminals. In addition to promoting Cl
influx, H2O2 may also
affect Cl extrusion mechanisms. Neurons
contain ATP-dependent Cl transporters,
and these transporters may become impaired because H2O2 can decrease the
ATP/ADP ratio (Tretter et al., 1997). Our model precludes any
significant effects of H2O2
directly on GABAA receptors, which have been
reported to be sensitive to modulation by redox agents (Pan et al.,
1995).
Hydrogen peroxide and other ROS alter synaptic inhibition, although the
exact mechanisms are not known (Muller et al., 1993; Pellmar, 1995,
Frantseva et al., 1998). A sustained increase in intracellular
Cl will decrease the
Cl gradient, and this should reduce
subsequent GABAA-mediated hyperpolarization. Our
findings are consistent with this process; the ability of muscimol to
induce Cl influx was reduced after
slices were exposed to
H2O2. Similarly, tonic
activation of GABAA receptors by "ambient"
GABA has been shown to elevate the resting
Cl permeability, and it causes a
positive shift in the reversal potential for
Cl and a decrease in inhibitory
transmission (Thompson and Gahwiler, 1989). Intense and repeated
activation of GABAA receptors has also been
reported to collapse the Cl
concentration gradient, leading to a positive shift in
ECl and a depolarizing response to
GABA (Lambert and Grover 1995). This process may be important in
conditions such as anoxia. In fact, Katchman et al. (1994) showed that
the anoxia-induced suppression of monosynaptic
GABAA receptor IPSCs in CA1 pyramidal neurons was
caused by an altered IPSC reversal potential. In our previous studies,
we also found that oxygen-glucose deprivation in the hippocampal slice
decreased GABA responses caused by increased [Cl]i (Inglefield and Schwartz-Bloom,
1998). Thus, when neurons are exposed to oxidative stress, increases in
intraneuronal Cl may explain the
reduction in synaptic inhibition mediated by GABAA receptors.
Using optical imaging techniques within the hippocampal slice, we have
demonstrated that exposure of neurons to mild oxidative stress produced
by H2O2 increases
Cl levels within hippocampal pyramidal
cell soma but not in interneurons. Impairment of
Cl gradients by
H2O2 may reduce the
efficacy of GABAA receptor-mediated inhibitory
transmission and potentiate neurodegenerative damage in conditions such
as Alzheimer's disease, Parkinson's disease, and aging.
| |
FOOTNOTES |
Received May 6, 1999; revised Aug. 2, 1999; accepted Aug. 12, 1999.
This work was supported by National Institutes of Health Grants 5 T32
AG00029 (R.S.) and NS28791 (R.D.S.). We gratefully acknowledge the
laboratory of Dr. J. Victor Nadler for analysis of HPLC samples and Dr.
George Somjen for helpful comments on this manuscript.
Correspondence should be addressed to Dr. Rochelle D. Schwartz-Bloom,
Department of Pharmacology and Cancer Biology, Box 3813, Duke
University Medical Center, Durham, NC 27710. E-mail:
schwa001{at}duke.edu.
| |
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ABSTRACT
INTRODUCTION
