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Next Article 
The Journal of Neuroscience, May 1, 1998, 18(9):3117-3123
Disruption of Mitochondrial Respiration Inhibits Volume-Regulated
Anion Channels and Provokes Neuronal Cell Swelling
Amanda J.
Patel,
Inger
Lauritzen,
Michel
Lazdunski, and
Eric
Honoré
Institut de Pharmacologie Moléculaire et Cellulaire, Centre
National de la Recherche Scientifique, UPR 411, 06560 Valbonne, France.
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ABSTRACT |
Hypoxia and inhibitors of mitochondrial respiration impair the
regulatory volume decrease (RVD) of cerebellar granule neurons after
hypotonic swelling. RVD is linked to the opening of volume-regulated anion channels (VRACs). VRACs are outwardly rectifying, inactivate slowly during maintained depolarization, and are permeable to the
cellular organic osmolyte taurine. Channel activation requires nonhydrolytic ATP binding and is not modulated by intracellular ADP.
VRAC opening is reversibly depressed by hypoxia and by mitochondrial inhibitors such as oligomycin, rotenone, and antimycin A. These results
demonstrate that neuronal VRAC activation and swelling are both tightly
linked to cellular energy. Moreover, the findings reported in this work
may have a particular significance for inherited mitochondrial human
diseases, such as mitochondrial myopathy, encephalopathy, lactic
acidosis, and stroke-like episodes (MELAS), which cause brain swelling
and edema.
Key words:
cerebellar granule neurons; RVD; chloride channels; ICln; hypoxia; mitochondrial encephalopathy
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INTRODUCTION |
Cell volume regulation has been
studied extensively in several mammalian systems, including epithelium,
cardiac cells, astrocytes, hepatocytes, and lymphocytes (for review,
see Strange et al., 1996 ). However, neuronal volume regulation
mechanisms remain largely unknown. Brain cells are normally protected
from volume alterations by a fine regulation of plasma osmolarity that
occurs in the kidney. However, both physiological neuronal activity and
brain pathologies lead to cell swelling and shrinkage (Lipton, 1973;
Ames and Nesbett, 1983; McBain et al., 1990). It is particularly well
known that anoxia and ischemia are associated with neuronal cell
swelling and subsequent tissue damage (for review, see Rothman and
Olney, 1986; Choi and Rothman, 1990; Choi, 1992). Neuronal swelling is also the hallmark of inherited human diseases caused by point mutations
in mitochondrial DNA, such as mitochondrial myopathy, encephalopathy,
lactic acidosis, and stroke-like episodes (the MELAS syndrome)
(Breningstall and Lockman, 1988; Castillo et al., 1995; James et al.,
1996; Valanne et al., 1996). The understanding of neuronal cell
regulatory volume mechanisms and their modulation by hypoxia could be
extremely valuable for designing novel therapeutic strategies for
treating some aspects of brain ischemic damage and edema.
During anisotonic swelling, cells have the ability to regulate their
volume by a regulatory volume decrease mechanism (RVD) (Strange et al.,
1996). RVD is linked to the activation of volume-regulated anion
channels (VRACs) and potassium channels. VRACs are permeable to various
anions and organic osmolytes, including polyols, methylamines, amino
acids, and their derivatives (Jackson et al., 1994, 1996; Pasantes-Morales et al., 1994, 1996; Sanchez-Olea et al., 1996; Hand et
al., 1997; Manolopoulos et al., 1997; Moran et al., 1997). RVD is
accomplished by a selective increase in these volume-sensitive membrane
permeabilities, with the accompanying loss of cellular water. These
osmoregulatory mechanisms are conserved from marine elasmobranchs
through mammals and are of fundamental importance for cells that must
adapt to changes in salinity concentration (Strange et al., 1996).
The present report shows that RVD in cerebellar granule cells is linked
to the activation of VRACs. We demonstrate that both RVD and VRAC
activation, after cell swelling, are impaired by hypoxia and by
inhibitors of mitochondrial respiration, and we discuss the possible
relevance of these findings for human pathologies.
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MATERIALS AND METHODS |
Cerebellar granule cell isolation and culture.
Cerebellar granule cells were isolated and cultured as described
previously (Varming et al., 1996). Cerebellar granule cells were
prepared from 6- to 7-d-old BALB/C mice (Charles River Laboratories).
Neurons were seeded on poly-L-lysine (50 µg/ml)-coated
dishes at a density of 2.5 × 106 cells/35 mm
culture dish and cultured in Eagle's Basal Medium (Sigma, St. Louis,
MO) supplemented with 10% fetal calf serum (Life Technologies,
Gaithersburg, MD), 25 mM KCl, 0.5%
penicillin-streptomycin. To prevent growth of glial cells, cytosine
arabinoside (10 µM) was added to the cultures 24 hr after
plating. We used 5- to 6-d-old cultures for all studies.
Cell volume measurements. For cell volume measurements, the
culture dishes were mounted on an inverted microscope (Olympus Optical,
Tokyo, Japan) equipped with differential interference optics and a 40×
oil-immersion objective lens. Images of neurons were sampled using a
video camera and stored as TIFF files. The circumference of the soma of
single neurons was measured on the monitor with the use of a mouse and
analyzed with National Institutes of Health image software. Image
acquisition and analysis allows detection of changes with an accuracy
of ±2-3% (Churchwell et al., 1996). Data are presented as means
associated with their SEs.
Saline solutions and electrophysiology of granule cells. For
cell volume studies, the standard external solution contained (in
mM): NaCl 78, KCl 3.2, MgCl2 0.5, CaCl2 1.1, HEPES 12, mannitol 150, glucose 15, pH 7.4 with
NaOH (340 mOsm). The hypotonic solution (190 mOsm) was the standard
solution except mannitol. Osmolarity was measured by the freezing point
procedure. Hypoxia was performed by bubbling saline solutions with pure
nitrogen for at least 30 min before and during the experiment.
Temperature, pH, and osmolarity were checked carefully throughout the
duration of the experimentation to ensure that these parameters did not
change. Solutions were applied to the cell with a peristaltic pump
(Gilson Medical Electric, Middleton, WI) at a flow rate of 5 ml/min.
For electrophysiology of granule neurons, the standard external
solution contained (in mM): TEACl 140, MgCl2 1, CaCl2 2.5, HEPES 10, mannitol 50, glucose 5, pH 7.4, with
TEAOH (355 mOsm). The hypotonic solution (300 mOsm) was the standard
solution except mannitol. In some experiments, external
Cl (140 mM) was substituted with
gluconate. To study ionic selectivity of the VRAC, TEACl was
substituted with either NaCl, NaSCN, NaBr, NaI, or Na gluconate. In
some experiments taurine permeability was assayed with an external
solution containing (in mM): taurine 280, Mg gluconate 1, HEPES 10, glucose 5, pH 8.2, with NaOH (300 mOsm). The internal medium
contained (in mM): Cs gluconate 155, MgCl2 3, EGTA 10, HEPES 10, ATPNa2 5, pH 7.2, with CsOH (350 mOsm). With gluconate and taurine solutions, a junction potential of  4 mV
was detected. In some outside-out experiments, internal gluconate was
substituted with Cl (as indicated in Results). For
cell-attached experiments, both the bath and pipette media contained
the standard external TEACl solution. The hypotonic solution was the
TEACl solution diluted by 30% (220 mOsm). Electrophysiological
procedures have been described previously elsewhere (Honoré et
al., 1992). Electrophysiological results are presented as means
associated with their SEs. n represents the number of cells
investigated in each experimental condition.
Cloning of ICln, Xenopus oocyte injection, and
electrophysiology. The rat ICln cDNA was cloned (accession number
D13985) as follows. A 770 bp fragment was amplified from
reverse-transcribed rat lung total RNA using primers
5'-CCGCTCGAGGTTCCTGTGGAGCAATG-3' and
5'-CCGCTCGAGTAAGT CACACGAGTCAT-3' containing XhoI
restriction sites. The fragment was digested with XhoI and
cloned into the vector pEXO, and the sequence was verified using an
automatic sequencer (Applied Biosystems, Foster City, CA). The vector
was linearized using XbaI to synthesize cRNA for injection
into oocytes. Oocyte isolation, injection, and culture has been
described previously elsewhere (Honoré et al., 1992). ICln
synthetic mRNA (3 ng) was injected into oocytes. The oocytes were
maintained at 25°C and assayed 48 hr after injection. For oocyte
electrophysiology of ICln, the standard external solution contained (in
mM): NaCl 96, KCl 2, MgCl2 2, CaCl2
1.8, HEPES 10, pH 7.4, with NaOH (215 mOsm). To lower external
Cl, 96 mm Cl was substituted
with gluconate. For recording of volume-activated Cl channels, the isotonic solution was (in
mM): CsCl 48, BaCl2 1, MgCl2 1, CaCl2 0.9, mannitol 110, HEPES 5, pH 7.4, with CsOH (220 mOsm). The hypotonic solution was the same as the isotonic solution except mannitol (110 mOsm). To lower external Cl,
48 mM Cl was substituted with
gluconate.
Pharmacological agents. Stock solutions of SITS, DIDS, and
5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB) were made in DMSO
at the concentration of 100 mM. Niflumic acid and
9-anthracen carboxylic acid were dissolved in 0.1 N NaOH at a
concentration of 100 mM. The oligomycin stock solution was
made in ethanol at a concentration of 2.5 mg/ml. Rotenone and antimycin
A were dissolved in ethanol at a concentration of 100 mM.
Solvents were always included in the control solutions. All chemicals
used in this study were purchased from Sigma.
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RESULTS |
Volume regulation of cerebellar granule cells was studied in
normoxic and hypoxic conditions. Hypoxia either was performed directly
by bubbling pure nitrogen or its effects were chemically mimicked using
oligomycin, a specific blocker of the F1 unit of the mitochondrial
ATPase. Figure 1A shows
that in normoxic conditions, granule cells regulate their volume during
an anisotonic challenge (also see inset in Fig.
1B). Decreasing the osmolarity from 340 to 190 mOsm
(constant ionic strength) led to a rapid swelling followed by a
decrease in cell volume (RVD). Cells recovered 55% of their initial
volume after 20 min of hypo-osmolarity. By contrast, during hypoxia, no
recovery occurred and cell swelling increased throughout the anisotonic
challenge. Figure 1B illustrates the volume
regulation after 20 min of hypo-osmolarity in normoxic, hypoxic, and
hypoxic-like conditions (oligomycin) and in the presence of the
Cl channel inhibitor SITS. During hypoxia or after
oligomycin treatment and in the presence of SITS, RVD was clearly
impaired. In isotonic conditions, no volume alteration was detected
after 30 min under hypoxic conditions or in the presence of SITS (not
shown).
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Figure 1.
Hypoxic inhibition of regulatory volume decrease
in cerebellar granule cells. A, Time course of cell
swelling and RVD in normoxic and hypoxic conditions. Ten cells were
analyzed in each condition, and means associated with their SEs are
illustrated. The isotonic and hypotonic osmolarities were 340 and 190 mOsm, respectively. B, Percentage of volume regulation
after 20 min in hypotonic conditions (190 mOsm). Thirteen cells were
analyzed in each condition. SITS and oligomycin concentrations were 100 µM and 2.5 µg/ml, respectively. Hypoxia and
pharmacological agents were applied in isotonic conditions for 4 min
before and during the hypotonic challenge. The inset
shows cell bodies in isotonic condition (340 mOsm) (left
panel), 4 min after hypotonic stimulation (middle
panel), and 20 min after hypotonic stimulation
(right panel).
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Figure 2A illustrates
the changes in membrane potential of a granule cell recorded with the
patch-clamp whole-cell configuration during hypotonic stimulation. To
block K+ channels and to avoid
Na+ channel current, the intracellular solution
contained Cs+ (instead of K+),
and the extracellular Na+ was substituted with
TEA+. Furthermore, internal free calcium was
chelated with EGTA and the internal Cl
concentration was kept low (6 mM). The contribution of
Cl channel activity to the setting of the resting
membrane potential was assayed by substituting external
Cl with gluconate. In isotonic conditions (355 mOsm), the cell was depolarized to positive values and removal of
external Cl led to small hyperpolarizations (a
junction potential of 4 mV was detected under these conditions). When
the cell was challenged with a hypotonic solution (300 mOsm), the cell
gradually polarized to more negative potentials (n = 9). Removal of external Cl (substituted with
gluconate) induced increasing depolarizations in hypo-osmotic
conditions (31 ± 4 mV; n = 9). Figure
2B shows the I-V curves of the
currents recorded in either isotonic or hypotonic conditions. The
current induced in hypotonic conditions was outwardly rectifying with a
reversal potential of 48.5 ± 1.5 mV (n = 31).
When most of the external Cl was substituted with
gluconate, the amplitude of the outward current was reduced
drastically, and the reversal potential was shifted to 18.8 ± 3.3 mV (n = 8). Figure 2C shows the current traces recorded during increasing depolarization pulses in hypotonic conditions. The outward current recorded in hypotonic conditions shows
a slow time-dependent inactivation at positive potentials. Figure
2D illustrates the pharmacology of the
Cl current activated by cell swelling. The
Cl current was sensitive to the classic
Cl channel blockers SITS, DIDS, NPPB, and niflumic
acid but was resistant to anthracene-9-carboxylic acid (9AC).
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Figure 2.
Volume-regulated anion channels in cerebellar
granule cells. A, Membrane potential recordings in
isotonic (355 mOsm) and hypotonic conditions (300 mOsm). The
contribution of Cl channels to the setting of the
resting membrane potential was assayed by substituting
Cl with gluconate (indicated by
arrows). B, Current-voltage relationship
of volume-sensitive anionic channels in isotonic and hypotonic
conditions. The holding potential was 80 mV, and the cell was
depolarized to 100 mV with a voltage ramp of 500 msec in duration.
C, Current traces recorded in hypotonic conditions (300 mOsm). The cell was held at 80 mV and depolarized to +50 mV by 10 mV
increments. D, Pharmacology of the granule cell VRAC.
Six cells were analyzed in each condition, and current amplitudes were
measured at +100 mV. SITS, DIDS, 9AC, and niflumic acids were added at
a concentration of 1 mM. NPPB concentration was 0.1 mM. In all experiments, cells were dialyzed with an
internal medium containing 6 mM Cl and
5 mM ATP.
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Figure 3 illustrates the single-channel
properties of the volume-sensitive Cl channels in
granule cells. Single-channel recordings at different membrane
potentials in an outside-out patch (6 mM intracellular Cl concentration) are shown in Figure
3A. Similar to that of whole-cell recordings, the
single-channel I-V curve was outwardly
rectifying (Fig. 3B). The inset in Figure 3C
shows that when external Cl was substituted with
gluconate, the amplitude of the outward current decreased, and the
reversal potential shifted to positive values. The single-channel
conductance measured between +30 and +70 mV was 36 ± 6 pS
(n = 6). External Cl was
substituted with various anions to study the ionic specificity of the
volume-sensitive anion channel (Fig. 3C). In these
experiments, the internal medium contained Cl
instead of gluconate. Reversal potentials were 2.4 ± 0.6 mV (n = 23), 14.6 ± 1.2 mV (n = 5), 7.8 ± 1.9 mV (n = 7), 4 ± 1.5 mV
(n = 7), +21.5 ± 0.8 mV (n = 7),
and +39 ± 0.4 mV (n = 8) in the presence of
external Cl, SCN,
I, Br, taurine, pH 8.2, and
gluconate, respectively (corrected from junction potentials). Current
amplitudes were measured in outside-out patches containing different
nucleotide conditions. Channel activity was significantly decreased
when intracellular ATP was omitted. When ATP was substituted with the
nonhydrolyzable analog AMP- , -imidoadenosine 5', triphosphate
(PNP), channel activity was similar to that recorded in the presence of
ATP. Furthermore, ADP was unable to substitute for ATP. Finally,
addition of ADP in the presence of ATP did not affect channel
activity.
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Figure 3.
Single-channel properties of granule cell VRAC.
A, Single-channel currents from an outside-out patch
recorded at different membrane potentials (as indicated) in hypotonic
conditions. The internal medium contained 6 mM
Cl and 5 mM ATP. B,
I-V curve of the patch illustrated in
A. The single-channel conductance measured between +30
and +70 mV was 36 pS. C,
I-V curves of an outside-out patch
constructed with a voltage ramp protocol in hypotonic conditions. The
holding potential was 60 mV, and the patch was depolarized to +80 mV
with a voltage ramp of 500 msec in duration. In this experiment
external Cl was substituted with various anions
(as indicated). The internal medium contained 161 mM
Cl. The inset shows
I-V curves of an outside-out patch
excised in the presence 6 mM internal
Cl. In this experiment the external
Cl concentration was reduced to 6 mM
by substitution with gluconate (bottom trace).
D, Role of intracellular nucleotides in VRAC activation.
Current amplitudes of outside-out patches measured at +80 mV in
different nucleotide conditions (as indicated). Eight patches were
analyzed in each condition. In these experiments the internal medium
contained 6 mM Cl, and the external
osmolarity was 300 mOsm.
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Figure 4A shows that
oligomycin (a specific blocker of the F1 unit of the mitochondrial
ATPase) and antimycin A (a proximal inhibitor of the mitochondrial
electron transport chain) induced reversible depolarizations of granule
cells dialyzed in the presence of 5 mM ATP and maintained
in hypotonic conditions (300 mOsm). Similarly, the whole-cell VRAC
current recorded in the presence of internal ATP was reversibly
inhibited by oligomycin in hypotonic conditions (Fig.
4B,C). Oligomycin inhibited the VRAC current at all
potentials (Fig. 4C). Figure 4D summarizes
the effects of several metabolic inhibitors on VRAC recorded in
hypotonic conditions (300 mOsm). Antimycin A and rotenone, which are
proximal inhibitors of the electron transport chain and oligomycin, an ATP synthase inhibitor, reversibly inhibited the whole-cell
Cl current recorded in the presence of internal
ATP. Similar inhibition of VRAC currents by oligomycin was observed in
other cell types, including simian virus 40 transformed African green
monkey kidney (COS), Madin-Derby canine kidney (MDCK), NIE115
neuroblastoma cells, and human monocytes (n = 10; data
not shown). No effect of 5 mM DTT (a strong reducing agent)
and of 0.5 mM diphenylene iodinium (DPI) [an inhibitor of
NADP(H) oxidase] was observed (n = 5; data not
shown).
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Figure 4.
Effects of chemical hypoxia on whole-cell VRAC
current of granule cells. A, Reversible depolarizations
induced by oligomycin (2.5 µg/ml) and antimycin A (10 µM) in a cell dialyzed with 5 mM ATP and 6 mM Cl. The cell was maintained in
hypotonic conditions (300 mOsm), and the contribution of
Cl to the setting of the membrane potential was
assayed by substituting external Cl with gluconate
(as indicated). B, Reversible effect of oligomycin on
the whole-cell VRAC current recorded in hypotonic conditions (300 mOsm). The current amplitude was measured at +80 mV. C,
Effects of oligomycin on the VRAC I-V
curve recorded with a voltage ramp. The holding potential was 60 mV,
and the cell was depolarized to +80 mV with a ramp of 500 msec in
duration. D, Effects of several metabolic inhibitors on
the whole-cell Cl current recorded in hypotonic
conditions (300 mOsm) and measured at +80 mV. Antimycin A and rotenone
concentrations were 10 µM; oligomycin concentration was
2.5 µg/ml. Eight cells were analyzed in each condition.
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Figure 5A shows that hypoxia
performed by bubbling pure nitrogen induced a reversible inhibition
(50.6 ± 9.3%; n = 5) of the Cl current
recorded in the cell-attached configuration under hypotonic conditions.
Similarly, treatments that mimic hypoxia (oligomycin, antimycin A, and
rotenone) reversibly inhibited Cl channel activity in
outside-out patches excised in the presence of internal ATP and
maintained in hypotonic conditions (300 mOsm). Similar data were
obtained with patches excised in the presence of either 5 mM AMP-PNP or 5 mM ATP/3 mM ADP
(data not shown). The single-channel conductance of VRAC was not
altered by these treatments, and inhibition was observed at all
potentials (Fig. 5C). Finally, Figure 5D shows
that hypoxia performed by bubbling nitrogen mimicked the effect of
antimycin A in an outside-out patch excised in the presence of internal
ATP.
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Figure 5.
Effects of hypoxia and inhibitors of mitochondrial
respiration on granule cell VRAC single channels. A,
Effects of hypoxia (5 min) performed with pure nitrogen on the
Cl current recorded in the cell-attached
configuration during a hypotonic stimulation (220 mOsm).
I-V curves recorded during hypoxia and
recovery are illustrated in gray. The holding potential
was 60 mV, and the patch was depolarized to +80 mV with a voltage
ramp of 500 msec in duration. B, Effects of oligomycin
(2.5 µg/ml), antimycin A (10 µM), and rotenone (10 µM) on the VRAC current recorded in an outside-out patch
in hypotonic condition (300 mOsm). The holding potential was +50 mV.
The internal medium contained 6 mM Cl
and 5 mM ATP. C, Reversible effects of
oligomycin (2.5 µg/ml) on the I-V
curve of VRAC (illustrated in gray) recorded in an
outside-out patch in hypotonic condition. The holding potential was
60 mV, and the patch was depolarized to +80 mV with a voltage ramp of
500 msec in duration. The internal medium contained 6 mM
Cl and 5 mM ATP. D,
Effects of hypoxia, performed with pure nitrogen, and antimycin A on
the VRAC current recorded in an outside-out patch in hypotonic
conditions (300 mOsm). The holding potential was +50 mV. The internal
medium contained 6 mM Cl and 5 mM ATP.
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In Figure 6, the effects of hypoxia
(nitrogen and oligomycin) were investigated on the native VRAC present
in Xenopus oocytes and on the Cl
channel current induced by ICln expression. In these experiments, K+ channels were inhibited with
Cs+ (substituting Na+) and
Ba2+. Hypotonic stimulation of native oocytes (110 mOsm) elicited an inward current measured at a holding potential of
60 mV. The inward current induced by hypotonicity was reversibly
inhibited by hypoxia (nitrogen or oligomycin) (Fig.
6A). The I-V curves of the
current induced by hypotonicity in native oocytes is illustrated in
Figure 6B. As in granule cells, the oocyte
volume-activated Cl current was outwardly
rectifying and reversed at 31 ± 6 mV (n = 12).
When Cl was omitted from the external medium,
outward current amplitude was decreased, and the reversal potential was
shifted to positive values (not shown). In Figure 6C,
oocytes were injected with the mRNA encoding the putative
Cl channel gene ICln. Similar to that of the
endogenous volume-activated Cl current, the
I-V curve of ICln was outwardly rectifying, and the reversal potential was 21 ± 4 mV in isotonic conditions
(n = 7). Substitution of external
Cl with gluconate shifted reversal potentials to
positive values and decreased the outward current (Fig. 6C).
The current was constitutively active in isotonic conditions and did
not require cell swelling for activation. Figure 6C shows
that neither nitrogen nor oligomycin inhibited the ICln-mediated
Cl current (n = 7).
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Figure 6.
Hypoxic inhibition of VRAC in
Xenopus follicular oocyte and lack of effect on
ICln-mediated Cl current. A,
Reversible inhibition by hypoxia (nitrogen and oligomycin) of the VRAC
current in a follicle-enclosed oocyte. The holding potential was 60
mV. The oocyte was challenged for 5 min with a hypotonic solution (110 mOsm) every 20 min. Nitrogen and oligomycin were applied 10 min before
and during the hypotonic stimulation. B,
I-V curve of the VRAC current of a
follicular oocyte in isotonic (220 mOsm) and hypotonic conditions (110 mOsm). The holding potential was 60 mV, and the oocyte was
depolarized to 100 mV with a voltage ramp of 500 msec in duration.
C, Effects of hypoxia (nitrogen and oligomycin) on the
ICln-mediated Cl current in a defolliculated
oocyte. Same parameters as B. In this experiment the
oocyte was bathed with the standard external solution (96 mM CsCl; 220 mOsm). External Cl
concentration was lowered by substituting 96 mM
Cl with gluconate.
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DISCUSSION |
We report the characterization and hypoxic modulation of the
volume-regulated anion channels in cerebellar granule cells and demonstrate their contribution to the RVD process. The granule cell
VRAC is outwardly rectifying, slowly inactivates during maintained depolarization at positive potentials, and has an anionic permeability of SCN > I > Br > Cl > taurine > gluconate. The granule cell VRAC is sensitive to the
Cl channel blockers SITS, DIDS, NPPB, and niflumic
acid, but is resistant to the calcium-activated Cl
channel blocker 9AC. The single-channel conductance of 36 pS is in the
range of the previously reported VRAC in C6 glial and epithelial cells
(Solc and Wine, 1991; Okada et al., 1994; Jackson and Strange,
1995).
Activation of granule cell VRAC requires the presence of
intracellular nonhydrolytic ATP. Because AMP-PNP, the nonhydrolyzable analog of ATP, can substitute for ATP, it is likely that ATP binding rather than ATP hydrolysis is involved. ATP could possibly bind directly to the channel or bind to an auxiliary regulatory protein. A
similar dependence of VRAC activation on internal ATP has been reported
previously in other cell types, including hepatocytes, C6 glial cells,
T lymphocytes, endothelial cells, and epithelial cells (Jackson et al.,
1994; Petersen et al., 1994; Ballatori et al., 1995; Jackson et al.,
1996; Manolopoulos et al., 1997).
During hypotonic challenge, we show that granule cells regulate their
volume (RVD). RVD was blocked by the Cl channel
inhibitor SITS, suggesting that Cl channel
activation is indeed involved in the process of RVD. Opening of these
Cl channels during cell swelling will allow an
efflux of Cl (and also of organic osmolytes),
which is accompanied by cellular water leading to RVD. Because
Cl is predominantly passively distributed across
the neuronal membrane, the steady-state equilibrium potential for
Cl ions and thereby the intracellular
Cl concentration is directly proportional to the
value of the cell resting membrane potential.
During hypoxia or when normal mitochondrial function was blocked by
oligomycin, RVD was impaired and cells remained swollen. In
cell-attached, whole-cell, or excised outside-out patches, hypoxia that
was performed with either metabolic inhibitors or pure nitrogen
reversibly inhibited the opening of VRACs. One possible explanation is
that both mitochondrial inhibitors and nitrogen-induced hypoxia may
directly affect VRAC channel functions. Another possible explanation is
that the effects of hypoxia, antimycin A, rotenone, and oligomycin are
mediated by inhibition of mitochondrial respiration. Inhibition of VRAC
activation in outside-out patches seems to be in favor of a direct
effect on the channels. Indeed, outside-out patches are usually
believed to be free of stored energy (i.e., mitochondria). However,
differential interference contrast light and high-voltage electron
microscopy studies have shown that excised patches are like small
pieces of cell rather than pieces of isolated membrane (Sokabe and
Sachs, 1991). Indeed, isolated outside-out patches contain cytoskeleton
and cellular organelles as well as membrane. The mitochondria present
in the patches therefore can provide an energy source. Because VRAC
opening requires intracellular ATP, one may suspect that the effects of
hypoxia could be mediated by a decrease in intracellular ATP. However,
the whole-cell and outside-out patches experiments were performed in
the presence of 5 mM internal ATP, suggesting that the
effects of hypoxia cannot be explained simply by a drop in
intracellular ATP level. Furthermore, granule cell VRAC is insensitive
to internal ADP, ruling out its possible involvement during hypoxic
inhibition. An alternative mechanism responsible for the hypoxic
inhibition of the neuronal cell volume regulation could be related to
the involvement of the electron transport chain, which is responsible
for the oxidation of NADH and is a site of intense oxygen consumption.
A significant portion of consumed oxygen is known to result in the
production of radicals and peroxides (Archer et al., 1993). Inhibition
of the proximal electron transport chain by rotenone and antimycin A
tends to make the cytosol more reduced (increased GSH and NADH levels
and decreased activated oxygen species). By contrast, oligomycin, which
is a specific blocker of the F1 unit of the mitochondrial ATPase,
stimulates mitochondrial respiration and thereby increases the
production of activated oxygen species from the electron transport chain. Because the present report shows that rotenone, antimycin A, and
oligomycin inhibit VRAC in a similar way, it is unlikely that activated
oxygen species and/or the redox status of the cell is involved in this
regulation. Further studies will be required to gain insights into the
exact molecular mechanisms involved in VRAC regulation.
The ubiquitous protein ICln was initially cloned in MDCK cells and
induces a constitutively active outwardly rectifying
Cl channel when expressed in Xenopus
oocyte (Paulmichl et al., 1992; Krapivinsky et al., 1994). ICln shares
biophysical and pharmacological properties of VRAC (Gschwentner et al.,
1996). It has been demonstrated recently that antisense
oligonucleotides and a monoclonal anti-ICln antibody inhibit the
endogenous VRAC in NIH/3T3 cells and Xenopus oocytes,
respectively (Krapivinsky et al., 1994; Gschwentner et al., 1995).
These data suggested that ICln encoded VRAC or played a role in the
regulation of this type of channel. In the present report, ICln was
expressed in Xenopus oocytes, and the effects of hypoxia
(nitrogen and oligomycin) were compared on both the native oocyte VRAC
(Ackerman et al., 1994; Arellano and Miledi, 1994, 1995; Hand et al.,
1997) and ICln-mediated Cl currents (Paulmichl et
al., 1992). Only native oocyte VRAC (similar to granule cell VRAC) is
reversibly inhibited by hypoxia and oligomycin. These results suggest
that ICln does not share all the properties of VRAC and that ICln
regulation does not depend on cellular energy. Several recent reports
(Voets et al., 1996; Buyse et al., 1997) also provide evidence against
a direct role of ICln in VRAC.
Chronic hypoxia is associated with cell swelling and subsequent
neuronal degeneration (Ames and Nesbett, 1983; Rothman and Olney, 1986;
Choi and Rothman, 1990; McManus et al., 1995). Oxygen and glucose
deprivation is associated with a large increase in extracellular
glutamate concentration, which is believed to mediate most of the toxic
effect of neuronal hypoxia (Choi and Rothman, 1990; Choi, 1992, 1994).
Both early swelling and later neuronal degeneration are indeed blocked
by the addition of NMDA receptor antagonists (Clark and Rothman, 1987;
Churchwell et al., 1996). An increase in intracellular
Cl associated with water influx, and subsequent
death associated with cell lysis, was shown to be the consequence of
chronic hypoxia and NMDA receptor activation (Rothman, 1985). The
present work has demonstrated that granule cells VRACs are reversibly
inhibited by hypoxia. During anisotonic swelling, hypoxic closing of
VRAC channels may represent a short-term physiological adaptive
response that limits the leak of essential cellular metabolites (such
as amino acids and derivatives, polyols, and methylamines, which are
also known to permeate VRAC) and therefore preserves cellular metabolism. Moreover, hypoxic inhibition of VRAC could contribute to
limit Cl influx during NMDA-induced cell
depolarization and therefore swelling and cellular injury.
A number of inherited human diseases, including MELAS (mitochondrial
myopathy, encephalopathy, lactic acidosis, and stroke-like episodes)
and MERRF (myoclonic epilepsy and ragged-red fibers), are associated
with a genetic defect of brain mitochondrial functions (Breningstall
and Lockman, 1988; Castillo et al., 1995; James et al., 1996; Valanne
et al., 1996). These genetic diseases lead to bioenergetically
incompetent mitochondria and are associated with significant swelling
of brain cells (three- to fourfold). In particular, cortical edema,
massive focal brain swelling, and laminar cortical necrosis are the
features of the MELAS syndrome. Our finding that VRAC activation is
required for proper neuronal volume regulation and is tightly coupled
to cellular energy might explain these cytopathic aspects of the MELAS
syndrome.
The development of a specific pharmacology for the neuronal VRACs would
probably be very useful for the future design of novel therapeutic
strategies to limit cellular damage that occurs during brain ischemia
and in inherited mitochondrial diseases.
| |
FOOTNOTES |
Received Jan. 16, 1998; accepted Feb. 4, 1998.
This work was supported by the Centre National de la Recherche
Scientifique. We thank Bristol Myers Squibb for an "Unrestricted Award." A.J.P. was funded by the Philippe Foundation and by the Marie
Curie European Economic Community program.
A.J.P. and I.L. contributed equally to this work.
Correspondence should be addressed to Michel Lazdunski, Institut de
Pharmacologie Moléculaire et Cellulaire, Centre National de la
Recherche Scientifique, UPR 411, 660 route des Lucioles, Sophia
Antipolis, 06560 Valbonne, France.
| |
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Top
Abstract
Introduction
