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Volume 17, Number 16,
Issue of August 15, 1997
pp. 6133-6141
Copyright ©1997 Society for Neuroscience
High Intracellular Cl Concentrations Depress
G-Protein-Modulated Ionic Conductances
Robert A. Lenz,
Thomas A. Pitler, and
Bradley E. Alger
Department of Physiology, University of Maryland School of
Medicine, Baltimore, Maryland 21201
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Numerous G-protein-modulated ionic conductances are present in
central neurons and play major roles in regulating neuronal excitability. Accordingly, endogenous factors that alter the operation of these conductances may have profound effects on neuronal function. We now report that several G-protein-modulated ionic conductances in
hippocampal neurons are very much altered when Cl
is the predominant anion in the recording electrode. We used both
sharp-electrode and whole-cell techniques in rat hippocampal slices to
determine whether hippocampal CA1 pyramidal cell properties are altered
by KCl-filled, as compared with KCH3SO3- or
K-gluconate-filled, electrodes. We studied the effects of the anions on
synaptically evoked GABAB responses and baclofen- and
serotonin-induced currents as well as on a voltage-activated cation
current, Ih. High intracellular concentrations of chloride
([Cl]i) depressed all the
responses without altering resting cell properties. Intermediate
[Cl]i reduced baclofen-induced
currents as well as Ih in a dose-dependent manner. In KCH3SO3-filled cells, equimolar
substitution of GTP S for Tris-GTP results in activation of a
K+ conductance that hyperpolarizes cells and lowers
their input resistance. These effects of GTPS were blocked in
KCl-filled cells. In view of the tight coupling between the G-protein
and activation of the GABAB-activated K+
conductance, the effect of Cl ions is likely to be
exerted either on the G-protein or the K+ channel
itself. We observed substantial effects of
Cli at concentrations that are
believed to exist during development in the CNS as well as during
pathological conditions, such as spreading depression. Thus, the
results we describe must be taken into consideration during such
physiological and pathological conditions as well as in experimental
studies of G-protein-modulated conductances.
Key words:
GABAB;
baclofen;
serotonin;
Ih;
spreading depression;
anions
INTRODUCTION
We have noticed that large
GABAB responses are rare in CA1 pyramidal cells when KCl is
the major constituent in the recording electrode solution (compare with
Fig. 1 in Pitler and Alger, 1992 ; Pham and Lacaille, 1996).
Chloride-dependent GABAA responses are reversed and very
large when intracellular chloride concentration ([Cl]i) is high, so it
appears that the GABAB response is reduced selectively.
Although several explanations are conceivable, it could be that high
[Cl]i affects GABAB
responses. However, no thorough study of this issue has been
performed.
Intracellular recording techniques offer many advantages for the study
of neuronal function. However, it has been known since the earliest
studies using intracellular techniques (Coombs et al., 1955) that the
ions present in the electrolyte solution in the intracellular electrode
diffuse into the cell being studied and can affect cellular properties.
Whole-cell voltage clamp is a very powerful and widely used technique
that has many advantages over traditional intracellular recording.
Access to, and control over, the internal milieu as well as improved
clamp control are major advantages of large-bore patch pipettes over
traditional high-resistance intracellular electrodes. However,
alterations of normal cellular constituents can compromise cellular
functioning drastically. Classic studies performed on the squid giant
axon established early on the variable ability of different anions to
restore action potential amplitude (Tasaki et al., 1965). Although often overlooked, high intracellular concentrations of anions (Cl, F,
gluconate, et cetera) can alter various
electrophysiological characteristics of excitable cells (Baker et al.,
1962; Adams and Oxford, 1983; Nakajima et al., 1992; Zhang et al.,
1994).
Because the normal intracellular concentration of
Cl is ~8 mM (McCormick, 1990) and
Cl-based patch electrode solutions often contain
~150 mM Cl, it is quite possible
that these abnormally high concentrations could affect the cell
adversely. High intracellular concentrations of KCl
([KCl]i) can modify G-proteins (Nakajima et al.,
1992) and K+ channels (Adams and Oxford, 1983).
Because these studies were performed on cardiac atrial cells and the
squid giant axon, respectively, and used very high ( 400
mM) [Cl]i, we
wanted to determine whether KCl affected mammalian central neurons at
concentrations that commonly are used in patch pipette solutions. Zhang
et al. (1994) reported that certain anions attenuate the slow
Ca2+-dependent K+ conductance in
hippocampal neurons but that this could be explained by an effect on
intracellular Ca2+ handling. If high
[Cl]i does affect G-protein-linked
responses, such as those mediated by GABAB receptor
activation, then conditions in which
[Cl]i is high, such as during
development, and during pathological conditions, such as spreading
depression (Lux et al., 1986), will affect those responses. We have
undertaken the present experiments to determine whether hippocampal CA1
pyramidal cell properties are altered by KCl-filled, as compared with
KCH3SO3- or K-gluconate-filled, electrodes. Our
results support the hypothesis that
[Cl]i attenuates in a dose-dependent
manner both GABAB- and serotonin-mediated currents in CA1
neurons as well as a voltage-activated cation current,
Ih. Moreover, the
[Cl]i effects are exerted at the
level of the G-protein-linked pathway.
A preliminary report of this work has appeared in abstract form (Lenz
et al., 1994).
MATERIALS AND METHODS
Preparation of slices. Adult male Sprague Dawley rats
(125-300 gm, 30-60 d) were anesthetized deeply with halothane and
decapitated. Both hippocampi were removed and placed on agar blocks in
a slicing chamber containing oxygenated, partially frozen saline. A
Vibratome (Technical Products International) was used to cut transverse slices at 400 µm intervals. Slices were transferred to a holding chamber where they were maintained at the interface of physiological saline and humidified 95% O2/5% CO2
atmosphere at room temperature. Slices were allowed at least 1 hr to
recover before being transferred to a submerged perfusion-type chamber
(Nicoll and Alger, 1981) where they were perfused with saline
(29-31°C) at 0.5-1 ml/min.
Solutions. The bath solution contained the following (in
mM): 124 NaCl, 25 NaHCO3, 3.5 KCl, 2.5 CaCl2, 2 MgSO4 or 2 MgCl2, 1.25 NaHPO4, and 10 glucose. When monosynaptic
GABAB responses were studied,
6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 20 µM), 2-amino-5-phosphonovaleric acid (APV; 50 µM), and
bicuculline (20 µM) were present in the saline to block
ionotropic glutamate- and GABAA-mediated responses,
respectively. CGP 35348 (1 mM) was used in some experiments
to antagonize GABAB receptors. This concentration blocked
the synaptic GABAB response completely as well as that mediated by a 2 min bath application of baclofen (5 µM).
Serotonin (10 µM) was bath-applied for 2 min.
Whole-cell patch electrodes had resistances of 3-6 M and were
filled with one of three solutions (in mM): (1) 150-160
KCH3SO3, 10 HEPES, 2 BAPTA, 0.2 CaCl2, 1 MgATP, 1 MgCl2, and 0.3 Tris-GTP, pH 7.25; (2) 150-160 KCl, 10 HEPES, 2 BAPTA, 0.2 CaCl2, 1 MgATP, 1 MgCl2, and 0.3 Tris-GTP, pH 7.25; (3) 150 KC6H11O7
(K-gluconate), 10 KCl, 10 HEPES, 2 BAPTA, 0.2 CaCl2,
1 MgATP, and 0.3 Tris-GTP, pH 7.25. For the experiments performed with
intermediate [Cl]i (see Fig. 5), the
electrode solution contained either 45 KCl and 120 KCH3SO3 or 65 KCl and 100 KCH3SO3 with 10 HEPES, 2 BAPTA, 0.2 CaCl2, 1 MgATP, 1 MgCl2, and 0.3 Tris-GTP, pH 7.25. In a few experiments, as noted, the nonhydrolyzable
analog of GTP, GTPS (0.3 mM), was substituted for
Tris-GTP. Intracellular recordings also were performed with sharp
electrodes having resistances of 40-100 M and filled with either 3 M KCl or 2 M
KCH3SO3.
Fig. 5.
Intermediate concentrations of
Cli reduce the baclofen-induced
current and Ih in a dose-dependent manner.
A, Ih was elicited by a 1 sec, 20 mV hyperpolarizing voltage step from a holding potential
between  55 and 58 mV. Ih was measured
from cells recorded with electrodes containing 3, 45, 65, and 155 mM Cl. The current obtained from cells
filled with 3 mM Cl was designated 0%
control, and the data were normalized to this. The dose-response curve
was obtained by fitting the data with a computer-generated best-fit
equation of the form: % block = % max. block · [KCl]/(EC50 + [KCl]). There was a 51% block of Ih at 155 mM
Cl and an EC50 of 42 mM.
The numbers of cells are indicated above the mean values. B, A 2 min bath application of 5 µM baclofen to cells filled with the same
[Cl]i as in A
produced a similar dose-response curve. The curve was obtained as in
A. Cl (155 mM) produced
a 65% block of the baclofen response with an EC50 of 58 mM.
[View Larger Version of this Image (14K GIF file)]
CNQX was purchased from Research Biochemicals International (Natick,
MA), and BAPTA was purchased from Molecular Probes (Eugene, OR). CGP
35348 was a generous gift from CIBA-Geigy (Basel, Switzerland). All
other drugs and chemicals were obtained from Sigma Chemical (St. Louis,
MO).
Whole-cell and intracellular recordings and data analysis.
CA1 pyramidal cell recordings were obtained either with conventional intracellular or the "blind" whole-cell patch-clamp recording technique (Blanton et al., 1989). Cells obtained with the whole-cell technique were voltage-clamped near their resting potential soon after
break-in. Acceptable cells had resting potentials equal to or greater
than 55 mV and input resistances >35 M (except those cells
recorded with GTPS; see below). Series resistance was <12 M at
the beginning of an experiment and was compensated by 60-70%. Cells
were discarded if series resistance increased to >30 M during an
experiment. Bipolar concentric stimulating electrodes (Rhodes
Electronics) were positioned in stratum radiatum (s. radiatum) to allow
orthodromic activation of CA1 pyramidal cells. Liquid junction
potentials between the three intracellular solutions and the
extracellular solution were measured according to the method of Neher
(1992). These junction potentials were small KCl (3 mV),
KCH3SO3 (4 mV), K-gluconate (11 mV)and were not corrected for.
An Axoclamp-2 (Axon Instruments, Foster City, CA) was used for all
experiments. Evoked synaptic currents or potentials were elicited at
0.2 Hz and were filtered at 2 kHz with an eight-pole Bessel filter
(Frequency Devices, Haverhill, MA) and digitized at 5 kHz by a Digidata
1200 analog-to-digital converter (Axon Instruments). Data also were
stored on a VCR-based tape recorder system (Neuro-corder DR-484, Neuro
Data Instruments) and played into a computer for off-line analysis with
pCLAMP 6.0 software (Axon Instruments). The effects of the three
intracellular solutions on various responses were assessed by one-way
ANOVA, followed by unpaired Student's t tests (SigmaStat,
Jandel Scientific, Corte Madera, CA). The significance level chosen was
p < 0.05, and all data are reported as mean ± SEM.
RESULTS
When evoking synaptic responses in hippocampal CA1 neurons, we
often observed that GABAB-mediated IPSPs were small or
nonexistent when recorded with KCl-filled electrodes. To test the
hypothesis of an interaction between high
[Cl]i and GABAB-mediated
responses, we began by examining synaptically evoked GABAB
IPSPs under different recording conditions.
High intracellular chloride
([Cl]i) inhibits synaptic
GABAB responses
In cells recorded with KCH3SO3-filled
high-resistance intracellular electrodes, a multiphasic synaptic
response is reliably observable when stimulation is given in s.
radiatum (Fig. 1; Davies et al., 1990).
To prevent the occurrence of an afterhyperpolarization (AHP), which
might contaminate the synaptic response, we used stimulus intensities
that produced EPSPs that were just subthreshold for action potential
initiation in the recorded cell. The initial depolarizing potential
(truncated) is the CNQX-sensitive EPSP, which is followed immediately
by a rapidly rising GABAA-mediated IPSP (labeled
f for fast). The prolonged hyperpolarization (labeled s for slow) is mediated by the activation of
GABAB receptors and can be blocked by the GABAB
receptor antagonist CGP 35348 (Dutar and Nicoll, 1988; Olpe and
Karlsson, 1990). The response in CGP 35348 (middle
traces) consists of the EPSP, followed by the
GABAA IPSP. Subtraction of the synaptic response obtained
in CGP 35348 (middle traces) from the response recorded in
control saline (left-hand column) reveals the
GABAB-mediated IPSP in isolation (right-hand column). The slow IPSP had a latency to peak of 190 msec and was blocked by 1 mM CGP 35348 (middle trace),
thereby confirming that it is a GABAB-mediated
response.
Fig. 1.
Synaptically evoked GABAB responses
are attenuated in cells filled with KCl. While recording
intracellularly with high-resistance electrodes in CA1 pyramidal cells,
we elicited synaptic responses by electrical stimulation in the CA1 s.
radiatum. The synaptic response recorded from a
KCH3SO3-filled cell consists of a depolarizing EPSP, followed by an IPSP with an initial rapid rise and slow phase
(left trace). The initial rapid phase of the IPSP
(f) is mediated by activation of
GABAA receptors and can be blocked by bicuculline (not
shown). The slow phase of the IPSP (s) is
mediated by activation of GABAB receptors and is blocked by
1 mM CGP 35348 (middle trace). The
right trace is a subtraction of the CGP 35348 trace from
the control trace and represents the GABAB-mediated slow
IPSP in isolation. The EPSPs recorded during control and in the
presence of CGP 35348 are 12 mV in amplitude and were truncated for
display purposes. In the KCl-filled cell (bottom
traces), the GABAA-mediated IPSP is depolarizing,
as is the EPSP, which together result in a 10 mV depolarization in
control and in the presence of CGP 35348. Subtracted traces
illustrating the GABAB-mediated response are superimposed
and expanded to demonstrate that the GABAB response in
KCl-filled cells is smaller than in
KCH3SO3-filled cells. Resting membrane
potentials were 62 mV in the KCH3SO3-filled cell and 60 mV in the KCl-filled cell. Similar results were seen in
three other KCH3SO3-filled and three other
KCl-filled cells.
[View Larger Version of this Image (10K GIF file)]
When the recording electrode contained 3 M KCl, the
GABAB component of the synaptic response was attenuated
(Fig. 1, bottom traces). The GABAA-mediated fast
IPSP is depolarizing in KCl-filled cells because the normal inward
driving force for Cl is reversed in these cells.
Addition of 1 mM CGP 35348 (middle trace)
blocked the small GABAB-mediated slow IPSP. The subtracted traces obtained from both KCl-filled and
KCH3SO3-filled cells are expanded and
superimposed to demonstrate that the CGP-35348-sensitive component in
the KCl-filled cell is clearly smaller than that recorded in the
KCH3SO3-filled cell. The KCl-filled cell
illustrated in Figure 1 displayed the largest GABAB
response of the four KCl-filled cells that we examined in this way.
Because these initial experiments were performed with high-resistance
(40-100 M) intracellular electrodes and because the diffusion of
small molecules from such electrodes is linearly related to the access
resistance, the diffusion of the electrode solution into the cell might
have been incomplete (Pusch and Neher, 1988). Moreover, cells could be
voltage-clamped more effectively with low-resistance electrodes.
Therefore, we used the whole-cell patch-clamp technique to insure
maximal dialysis of the neuron with the electrode solution and to
improve clamp control. To isolate the evoked GABAB
response, we added CNQX (20 µM), APV (50 µM), and bicuculline (20 µM) to the bathing
solution to block ionotropic glutamate and GABAA receptors,
respectively. Orthodromic activation of CA1 neurons was achieved by a
stimulating electrode placed within s. radiatum on the CA3 side of the
recording electrode, but no more than 0.5 mm from it. For each cell the
maximum GABAB response was obtained by stimulating at
intensities up to 800 µA for 70 µsec or until further increases in
intensity did not result in an increased current. Each cell was
voltage-clamped at 55 mV to minimize contributions of different
driving forces to the magnitude of the synaptic current. Low-frequency
(0.2 Hz) high-intensity stimulation invariably elicited a monosynaptic GABAB response when we recorded from a
KCH3SO3-filled cell (Fig. 2A; Davies et al.,
1990). This synaptic current displayed paired-pulse depression, was
occluded by baclofen application, and was blocked completely by 1 mM CGP 35348, thus indicating it was a
GABAB-mediated current (data not shown). However, when KCl
was the main electrolyte in the electrode solution, the monosynaptic
GABAB responses were much smaller. The mean maximum
monosynaptic GABAB IPSC from seven KCl-filled cells
(25.3 ± 6.9 pA) was significantly less than the mean response
from eight KCH3SO3-filled cells (64.4 ± 8.1 pA) (Fig. 2B; p < 0.005).
Fig. 2.
Monosynaptically evoked GABAB
responses recorded under whole-cell voltage clamp are greatly reduced
in cells containing high intracellular [Cl].
A, Monosynaptic GABAB responses were
elicited by electrical stimulation in s. radiatum in the presence of 20 µM CNQX, 50 µM APV, and 20 µM
bicuculline. Traces are from two cells, one recorded with a patch
electrode solution containing 155 mM
KCH3SO3 (open bar) and the other
with a solution containing 155 mM KCl (filled bar). B, Bar graph showing that the average peak
monosynaptic GABAB response recorded from KCl-filled cells
(25.3 ± 6.9 pA, n = 7) is significantly
smaller than from KCH3SO3-filled cells (64.4 ± 8.1 pA, n = 8; p < 0.005).
[View Larger Version of this Image (9K GIF file)]
Baclofen and serotonin responses are reduced in
KCl-filled cells
To determine whether high [Cl]i
affected responses mediated by extrasynaptic as well as synaptic
GABAB receptors and to insure that we were activating
maximal numbers of GABAB receptors in all cells, we
bath-applied baclofen for brief periods. Bath application of baclofen
directly hyperpolarizes cells by activating GABAB receptors
(Newberry and Nicoll, 1984), which activate an outward current carried
by K+ ions (Gahwiler and Brown, 1985). Figure
3A illustrates that a 2 min
bath application of 5 µM baclofen causes a large outward current in KCH3SO3-filled cells. However, the
same application of baclofen to a KCl-filled cell voltage-clamped at
the same resting potential (60 mV) results in a substantially smaller
current. As is shown in Figure 3B, the mean baclofen current
measured from KCl-filled cells (43 ± 2.7 pA, n = 10) is significantly less than that measured in
KCH3SO3-filled cells (122 ± 19.2 pA,
n = 15; p < 0.005). These results
confirm that GABAB responses are smaller in KCl-filled
cells. We determined the conductance of the baclofen response by a
series of 200 msec voltage steps between 50 and 110 mV before and
during the peak baclofen response. Subtraction of the conductance
obtained during the control period from the conductance during the peak
baclofen response gave the baclofen conductance. As shown in Figure
3C, baclofen conductance in KCl-filled cells was
significantly smaller (1.5 ± 0.18 nS, n = 4) than
the baclofen conductance measured in
KCH3SO3-filled cells (4.2 ± 0.49 nS,
n = 5; p < 0.005). There was no
significant difference in the reversal potentials of the baclofen
currents of KCl-filled, as compared with
KCH3SO3-filled, cells.
Fig. 3.
Baclofen and serotonin responses are reduced in
KCl-filled cells. A, Traces of outward currents elicited
by a 2 min bath application of 5 µM baclofen recorded
under whole-cell voltage clamp. The three traces are from three
separate cells recorded with intracellular solutions, based on three
different salts: KCH3SO3 (155 mM),
KCl (155 mM), and K-gluconate (150 mM). All
cells were voltage-clamped between 58 and 60 mV. Downward
deflections in the KCl trace are spontaneous IPSCs. B,
Group data showing peak baclofen responses recorded with the three
different intracellular solutions. Baclofen responses recorded in
KCl-filled cells (filled bar) are significantly reduced, as compared with those in either
KCH3SO3-filled (open bar) or
K-gluconate-filled (open bar) cells
(p < 0.005), whereas responses in
KCH3SO3-filled and K-gluconate-filled cells
were not different (p = 0.62).
C, Baclofen I-V plot for four KCl-filled and five KCH3SO3-filled cells. The line is fit
to the data points by linear regression analysis. Baclofen conductance
was obtained by averaging the slopes of the linear portions of the
I-V plots from each cell. D, Bath
application of 10 µM serotonin for 2 min elicited an
outward current similar in amplitude and duration to baclofen, which
was greatly reduced in Cl-filled cells. Serotonin
responses from four KCl-filled cells are significantly less than those
measured in five KCH3SO3-filled and six
K-gluconate-filled cells (p < 0.02).
Serotonin responses from KCH3SO3-filled and
K-gluconate-filled cells were not different (p > 0.7).
[View Larger Version of this Image (24K GIF file)]
To determine whether high [Cl]i was
responsible for the decreased GABAB-mediated currents, we
repeated the baclofen application to cells filled with a
K-gluconate-based intracellular solution. Baclofen responses measured
from K-gluconate-filled cells (107 ± 10.8 pA, n = 7) were not statistically different from those measured from
KCH3SO3-filled cells (p > 0.5). However, the mean baclofen response in KCl-filled cells was
significantly smaller than the response obtained from cells filled with
K-gluconate (p < 0.005). Thus it appears that
the Cl ion per se causes the decrease in
GABAB-receptor-mediated responses.
The reduced GABAB response recorded from cells with high
[Cl]i could be produced by
Cl acting at any one of several sites within the
cell. The chloride ions could interact with the GABAB
receptor specifically, which could result in a decreased ability of an
agonist to activate the receptor, or they could interact with the
G-protein or the K+ channel to which the receptor is
coupled. To address the possibility that high
[Cl]i interacts specifically with
the GABAB receptor, we briefly bath-applied (2 min) 10 µM serotonin (5-HT) to cells filled with the different
electrode solutions. GABAB and 5-HT1a receptors appear to be coupled via G-proteins to the same K+
channel (Andrade et al., 1986). If the effects of
Cl are specific to the
GABAB-receptor-mediated response, then the outward current
elicited by activation of serotonin receptors should be of similar
magnitude irrespective of the electrode solution. As illustrated in
Figure 3D, this is not the case. Serotonin produced a
similar current in both KCH3SO3-filled
(121 ± 4.8 pA, n = 6) and K-gluconate-filled
(124 ± 16.9 pA, n = 5; p > 0.5)
cells, whereas in KCl-filled cells the mean 5-HT response was reduced significantly (55 ± 11.9 pA, n = 4;
p < 0.05). These data support the idea that high
[Cl]i mediates its effects, not via
specific interaction with the GABAB receptor per se, but
rather via interaction either with the G-protein involved in coupling
the receptors to the K+ channel or with the
K+ channel itself.
Ih is greatly reduced in
Cl-filled cells
To determine whether high [Cl]i
affects currents other than those mediated by neurotransmitter
receptors, such as GABAB and 5-HT, we investigated the
effects of various intracellular solutions on the hippocampal
Ih. The Ih is a
hyperpolarization-activated inward cationic current found in
hippocampal CA1 pyramidal cells (Halliwell and Adams, 1982; Maccaferri
et al., 1993). This slowly activating current is thought to be mediated
by a nonspecific, monovalent cationic conductance and is highly
regulated by numerous neurotransmitters that act via G-proteins
(Bobker and Williams, 1989; Jiang et al., 1993; Maccaferri and
McBain, 1996). Figure 4A illustrates that a
20 mV, 1 sec hyperpolarizing voltage step from 60 mV given ~5 min
after break-in produces an inwardly relaxing current associated with a
membrane conductance increase, Ih, that is greatly reduced in cells with high
[Cl]i. The group data in Figure
4B demonstrate that the Ih
measured in KCH3SO3- and K-gluconate-filled
cells did not differ (KCH3SO3: 169.2 ± 11.2 pA, n = 28; K-gluconate: 175.0 ± 17.1 pA,
n = 9; p > 0.7), whereas the
Ih from KCl-filled cells was significantly smaller than either (82.3 ± 5.7 pA, n = 20;
p < 0.001).
Fig. 4.
Ih is reduced in cells
with high [Cl]i. A,
Ih was elicited by giving a 1 sec, 20 mV
hyperpolarizing voltage step from rest shortly after breaking into the
cell. Magnitudes of Ih recorded from three
different cells with whole-cell patch electrodes filled with three
different solutions are displayed as the slowly activating inward
current. Ih from the illustrated traces are
KCH3SO3, 160 pA; KCl, 60 pA; and
K-gluconate, 180 pA. B, Group data showing the mean
Ih from cells filled with
KCH3SO3 (n = 28), KCl
(n = 20), and K-gluconate (n = 9). The Ih measured in
Cl-filled cells is significantly smaller than that
measured in either the KCH3SO3-filled or
K-gluconate-filled cells (p < 0.0001). All cells were voltage-clamped between 55 and 58 mV.
[View Larger Version of this Image (14K GIF file)]
To determine whether high [Cl]i
reduced the maximal Ih or whether it shifted the
voltage dependence of activation to more negative potentials, we
maximally activated Ih by giving a series of 2 sec hyperpolarizing voltage steps from 57 to 117 mV in 10 mV
increments (data not shown). The conductance of the
Ih between 117 and 67 mV was determined from
linear regression of the slope of the linear portion of the current
versus voltage (I-V) plot. The conductance of
Ih measured from KCl-filled cells was
significantly smaller (5.89 ± 0.84 nS, n = 7)
than that measured in KCH3SO3-filled cells
(17.2 ± 1.5 nS, n = 7; p < 0.0005). Furthermore, linear extrapolation of the averaged data in the
I-V plot from both KCl-filled and
KCH3SO3-filled cells intersected the ordinate
at the same voltage, indicating that the voltage dependence of
activation was not changed. Together these indicate that high
[Cl]i reduced the maximal
Ih.
Because it was apparent that high concentrations of
Cl were quite effective at reducing both
GABAB-mediated current and the G-protein-modulated
Ih, we wanted to determine the effects of intermediate [Cl]i on these
currents. Cells filled with 45 or 65 mM KCl displayed reduced baclofen-induced currents and Ih,
as compared with KCH3SO3-filled cells. Figure
5 is a graphical representation of these
data, which were fit by a computer-generated hyperbolic equation of the
form % block = (% max. block)([KCl])/(EC50 + [KCl]). Assuming that maximal block occurred at 155 mM
Cl and that no block was present with 0 mM Cl, the EC50 was 42 mM for block of Ih and was 58 mM Cl for block of the
baclofen-induced current. Thus,
[Cl]i reduces
GABAB-mediated currents as well as the voltage-activated, G-protein-modulated Ih in a dose-dependent
manner.
Cl effects on GTPS
Because the depressant effects of high
[Cl] i were not restricted to a
single G-protein-linked neurotransmitter receptor or ion channel type,
we considered the possibility that high
[Cl]i might interfere with the
G-protein pathway more directly. To do so, we investigated cells to
which the hydrolysis-resistant analog of GTP (guanosine
5 -O-13-thiotriphosphate, GTPS), an activator of
G-proteins, was applied internally. It has been suggested that GTPS
activates the same K+ channels that are activated by
both baclofen and 5-HT (Andrade et al., 1986). Indeed, we found that
application of either baclofen or 5-HT had no additional effect on
cells recorded with GTPS-filled electrodes (n = 2;
data not shown), as expected if the neurotransmitter-linked channels
already had been opened by the GTP analog. In agreement with previous
reports (Andrade et al., 1986), we observed that, in
KCH3SO3-filled cells, equimolar substitution of
GTPS for Tris-GTP resulted in a significantly more negative resting
potential (GTP: 60 ± 0.8 mV, n = 21; GTPS:
74 ± 2.0 mV, n = 5; p < 0.0001) and low input resistance (GTP: 62 ± 3.6 M,
n = 24; GTPS: 25 ± 2.3 M, n = 5; p < 0.0001) (Fig.
6). However, we found that, in KCl-filled
cells, substitution of GTPS for Tris-GTP did not result in
significant differences in either membrane potential (GTP: 60 ± 0.9 mV, n = 13; GTPS: 63 ± 2.0 mV,
n = 8; p > 0.08) or input resistance
(GTP: 67 ± 3.2 M, n = 20; GTPS: 60 ± 4.6 M, n = 8; p > 0.2). Application
of baclofen to KCl-filled cells containing GTPS produced only a
small outward current (30 ± 7.6 pA, n = 3), which
decayed approximately three times more slowly than that in
Tris-GTP-containing cells. Thus, high
[Cl]i blocks the effects of GTPS
on input resistance and resting membrane potential.
Fig. 6.
High [Cl]i
blocks the effects of GTPS on input resistance and resting membrane
potential. Substituting 300 µM GTPS for 300 µM Tris-GTP in the whole-cell recording electrode reduces
input resistance in, and hyperpolarizes significantly, cells recorded with KCH3SO3 electrodes by activating a
K+ conductance (p < 0.0001). Contrariwise, in cells filled with KCl there was no
significant difference in either input resistance or resting membrane
potential when equimolar GTPS was substituted for GTP. Additionally,
there was no difference in input resistance or resting membrane
potential between KCl-filled and KCH3SO3-filled cells recorded with 300 µM Tris-GTP
(p > 0.2).
[View Larger Version of this Image (18K GIF file)]
DISCUSSION
The results of this study show that high
[Cl]i significantly reduces
G-protein-modulated currents in CA1 neurons. We found that monosynaptic
GABAB currents in KCl-filled cells are greatly reduced, as
compared with those in KCH3SO3-filled cells.
Furthermore, the responses to brief applications of both baclofen and
5-HT were smaller in cells filled with high
[Cl]. Interestingly, the effects of
Cl ions were not limited to
neurotransmitter-activated K+ currents. The
voltage-dependent, nonspecific cation current, Ih, was reduced as well. Finally, high
[Cl]i blocked the effects of GTPS
on resting membrane potential and input resistance that normally are
seen in KCH3SO3-filled cells. We conclude that
high [Cl]i affects cellular
properties by interacting with G-protein-modulated ionic
conductances.
It is difficult to determine which intracellular site(s) the
Cl ions affect. Because the currents elicited by
both baclofen and 5-HT were similarly reduced in KCl-filled cells, as
compared with those in KCH3SO3-filled or
K-gluconate-filled cells, it is unlikely that Cl
ions interact directly with the GABAB receptor or a unique
GABAB-receptor-linked pathway. The observations that
Ih was reduced in KCl-filled cells and that high
[Cl]i blocked the effects of GTPS
on a K+ conductance further argue against a unique
interaction with the GABAB receptor. This is an important
point, because the G-protein activated by the GABAB
receptor is coupled very tightly (Andrade et al., 1986) to the inwardly
rectifying K+ channel that mediates the
GABAB response (Gahwiler and Brown, 1985). The model is
that these channels are gated directly by the activated G-protein. If
indeed the effects of [Cl]i occur at
a site downstream of the receptor, then it would seem that there are
few possible sites of action. Two equally tenable, nonexclusive
explanations are that high [Cl]i
interferes with the normal functioning of either the G-proteins or the
membrane channels themselves.
There is precedent for both of these possibilities. Anions affect
G-proteins (Higashijima et al., 1987) and G-protein-mediated activation
of K+ channels (Nakajima et al., 1992), and in both
cases Cl was the most potent anion tested. Another
possibility is that Cl ions do not affect the
G-protein but, rather, interact directly with monovalent cation
channels. The possibility that high
[Cl]i can modulate cation channels
in the squid axon has been suggested. Adelman et al. (1966) found that
sodium currents in squid axons progressively decline when the axon is
perfused with high concentrations of KCl, and Cl
ions suppress the amplitude and activation rate of delayed rectifier K+ currents in these axons (Adams and Oxford, 1983).
Our results would support an interaction with two separate channels:
(1) the K+ channel activated by GTPS as well as
by GABAB and 5-HT receptor activation, and (2) the
nonselective cation channel mediating Ih.
Velumian et al. (1996) reported that Ih was
greatly reduced when internal
CH3SO4 was replaced with
Cl or gluconate. Our findings
primarily agree with theirs, although we did not find that K-gluconate
depressed Ih. This difference can be explained most easily as a difference in Ca2+ buffering,
because Velumian et al. (1996) found that addition of 1-3
mM BAPTA to their internal recording solution could
"rehabilitate" the attenuated Ih obtained
from K-gluconate-filled cells. Zhang et al. (1994) reported that high
[Cl]i appeared to inhibit the slow
voltage-independent, Ca2+-activated
K+ AHP in hippocampal cells, although they also
suggested that Cl ions might act simply by
disrupting Ca2+ homeostasis.
Our results cannot be explained by secondary effects on
Ca2+, because our buffering conditions always
included 2 mM BAPTA, and the data constitute good evidence
that indeed Cl can affect G-protein-linked
conductances more directly. In view of the number of disparate channel
types influenced by Cl, it is tempting to
speculate that Cl affects some common
intermediary, such as the G-protein itself.
GABAB receptor activation underlies many important
physiological phenomena, such as synaptic inhibition and paired-pulse
depression (Davies et al., 1990; Pitler and Alger, 1994), and it has
been shown that GABAB receptor antagonists block LTP
induction by certain stimulation protocols (Olpe and Karlsson, 1990;
Davies et al., 1991). Ih and various
Ih-like currents have been characterized widely
in several mammalian nerve preparations (Mayer and Westbrook, 1983;
Maccaferri et al., 1993) as well as in cardiac atrial cells [referred
to there as If (DiFrancesco et al., 1986)].
This current plays an integral role in the slow rhythmic burst-firing
properties of thalamic relay neurons (McCormick and Pape, 1990), in
pacemaking the action potential characteristics of O-A interneurons in
the hippocampus (Maccaferri and McBain, 1996), and in the pacemaker current of sino-atrial myocytes. Therefore, disruption of these physiological properties by introduction of high
[Cl]i may seriously alter the normal
functioning of the cell and obscure correct interpretation of the
electrophysiological recordings.
Indeed, there are many examples in which high
[Cl]i is correlated with reduced or
absent GABAB responses. Using perforated patch to study the
developmental change in the GABAA receptor reversal
potential in embryonic and early postnatal rat neocortical cells, Owens
et al. (1996) reported that [Cl]i is
high (27-37 mM) at young ages and decreases with
development. Luhmann and Prince (1991) found that baclofen-induced
responses essentially were absent from newborn rat cortical neurons.
Interestingly, both somatic and dendritic GABAB responses
matured during the second and third postnatal week, simultaneous with a
shift of EGABAA to more
hyperpolarized potentials because of decreasing [Cl]i. Misgeld et al. (1984) found
that baclofen produced only slight hyperpolarizations and small
conductance increases in granule cells, whereas it elicited large
hyperpolarizations accompanied by large conductance increases in CA3
cells. EGABAA was depolarized significantly more in the granule cells than in the CA3 cells, thus
implying a higher [Cl]i in granule
cells. It is also possible that the apparent difficulty in observing
GABAB-mediated miniature IPSCs (Alger and Nicoll, 1980;
Otis and Mody, 1992) is related in part to the use of
Cl-based solutions in these experiments.
Furthermore, it is interesting to note that investigators have had
difficulty obtaining functional expression of GABAB
receptors in Xenopus oocytes, which have high resting
[Cl]i (~35 mM).
In light of our finding that
[Cl]i ~40 mM can
reduce GABAB and Ih currents
significantly, it appears that there are many instances (such as during
development) when Cl can reach concentrations that
will interfere with these currents and potentially compromise normal
cellular functioning. These results may be particularly relevant to the
understanding of pathophysiological phenomena, such as spreading
depression, thought to involve massive influx of
Cl (Lux et al., 1986). Our results suggest that
some of the K+ conductances potentially available
for repolarizing strongly depolarized cells and limiting the extent of
pathological activity would, in fact, be compromised by high
[Cl]i. Reducing GABAB
conductance in particular should contribute to more pronounced
epileptiform activity (Traub et al., 1993). Our data support the
growing recognition that internal anions may have important influences
on cellular excitability in the CNS.
FOOTNOTES
Received March 26, 1997; revised June 4, 1997; accepted June 6, 1997.
This work was supported by United States Public Health Service Grants
NS30219 and NS22010 (B.E.A.). R.A.L. was supported by National
Institutes of Health Neurosciences Training Grant NS07375. We thank
Drs. F. Le Beau and W. Morishita, as well as L. Martin, S. Mason, and
N. Varma, for their comments on a draft of this manuscript. This
manuscript will comprise part of a thesis submitted in partial
fulfillment of the Ph.D. degree requirements of R.A.L. We thank E. Elizabeth for expert word processing and editorial assistance.
Correspondence should be addressed to Dr. B. E. Alger, Department
of Physiology, University of Maryland School of Medicine, 665 West
Baltimore Street, Baltimore, MD 21201.
Dr. Pitler's present address: Neurogen Corporation, 35 Northeast
Industrial Road, Branford, CT 06405.
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