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The Journal of Neuroscience, April 15, 1999, 19(8):2960-2973
Single-Channel Properties of Synaptic and Extrasynaptic
GABAA Receptors Suggest Differential Targeting of Receptor
Subtypes
Stephen G.
Brickley,
Stuart G.
Cull-Candy, and
Mark
Farrant
Department of Pharmacology, University College London, London WC1E
6BT, United Kingdom
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ABSTRACT |
Many neurons express a multiplicity of GABAA receptor
subunit isoforms. Despite having only a single source of inhibitory input, the cerebellar granule cell displays, at various stages of
development, more than 10 different GABAA subunit types.
This subunit diversity would be expected to result in significant
receptor heterogeneity, yet the functional consequences of such
heterogeneity remain poorly understood. Here we have used
single-channel properties to characterize GABAA receptor
types in the synaptic and extrasynaptic membrane of granule cells. In
the presence of high concentrations of GABA, which induced receptor
desensitization, extrasynaptic receptors in outside-out patches from
the soma entered long-lived closed states interrupted by infrequent
clusters of openings. Each cluster of openings, which is assumed to
result from the repeated activation of a single channel, was to one of
three main conductance states (28, 17, or 12 pS), the relative
frequency of which differed between patches. Such behavior indicates
the presence of at least three different receptor types. This
heterogeneity was not replicated by individual recombinant receptors
( 1 2 2S or
132S), which gave
rise to clusters of a single type only. By contrast, the conductance of
synaptic receptors, determined by fluctuation analysis of the synaptic
current or direct resolution of channel events, was remarkably uniform
and similar to the highest conductance value seen in extrasynaptic
patches. These results suggest that granule cells express multiple
GABAA receptor types, but only those with a high
conductance, most likely containing a subunit, are activated at the synapse.
Key words:
cerebellar granule cell; GABAA receptor; synaptic; single channel; subunit heterogeneity; differential
targeting
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INTRODUCTION |
GABA is the principal inhibitory
neurotransmitter in the CNS, acting on ionotropic GABAA
receptors and metabotropic GABAB receptors.
GABAA receptors are heteropentamers formed from multiple subunit types. To date, nineteen different mammalian subunit genes have
been described (1-6, 1-4,
1-3,  ,  ,  , and  1-3), with
further diversity arising from alternative splicing. Except for the subunits, which assemble independently, and the subunit, which
occurs outside the CNS, GABAA receptors can be formed from
a pool of some 20 different subunits, inclusive of splice variants (for
review, see Barnard et al., 1998 ). Many neurons express multiple
subunit types (Laurie et al., 1992; Wisden et al., 1992) and would be
expected to display significant receptor heterogeneity, even allowing
for restrictions governing subunit assembly (Connolly et al., 1996a;
McKernan and Whiting, 1996). Numerous studies of recombinant receptors
have shown that the biophysical and pharmacological properties of
GABAA receptors depend critically on their subunit
composition (for review, see Macdonald and Olsen, 1994), yet the
functional consequences of receptor multiplicity remain poorly
understood. For a number of transmitters, it has been suggested that
distinct receptor subtypes may be targeted to specific regions of the
neuronal membrane, possibly enabling cells to respond in different ways
to the same transmitter. For GABAA receptors, specific
targeting mechanisms have been proposed (Connolly et al., 1996b;
Fritschy et al., 1998). Furthermore, immunohistochemical studies have
provided direct evidence for segregation of subunit proteins within
individual neurons (Koulen et al., 1996; Nusser et al., 1996, 1998;
Fritschy et al., 1998).
Cerebellar granule cells express a particularly wide range of
GABAA subunits, despite having a relatively simple
morphology and receiving most of their inhibitory input from one cell
type. Granule cells originate from progenitors in the external germinal layer, from where they migrate through the molecular layer, past the
Purkinje cells, to take up their final positions in the internal granule cell layer. Here they receive GABA-mediated inhibitory input
from Golgi cells (Eccles et al., 1967; Bisti et al., 1971; Hámori
and Takács, 1989). In the rat, these processes take place during
the first 3 postnatal weeks. In situ hybridization and immunohistochemical data indicate that granule cells express, at
various developmental stages, more than 10 different GABAA subunits (for review, see Wisden et al., 1996). Indeed, even before synapse formation, granule cells in the external germinal layer contain
mRNA for five subunits (2,
3, 3,
1, and 2) (Laurie et al.,
1992; Zdilar et al., 1992), and whole-cell patch-clamp recordings have
shown that they express functional GABAA receptors (Farrant
et al., 1995). In this study, we have sought to determine whether this
diversity of subunit expression is reflected in the functional
properties of synaptic and extrasynaptic GABAA receptors. Specifically, we have examined the single-channel properties of GABAA receptors in granule cells before and immediately
after synapse formation. Our results suggest that granule cells express multiple GABAA receptor types, but possess mechanisms
capable of differentially targeting these receptors, such that only a selected subset is incorporated into the postsynaptic membrane.
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MATERIALS AND METHODS |
Cerebellar slices. Recordings were made from both
premigratory and postmigratory cerebellar granule cells (external
germinal layer and internal granular layer, respectively) in
parasagittal slices (250 µm) obtained from 7-d-old (P7) Sprague
Dawley rats. Slices were prepared and maintained as described
previously (Farrant and Cull-Candy, 1991; Farrant et al., 1994). In
brief, the animal was decapitated, and the brain was rapidly removed
and placed in ice cold "slicing" solution composed of (in
mM): NaCl 125, KCl 2.5, CaCl2 1, MgCl2 4, NaHCO3 26, NaH2PO4 1.25, glucose 25, pH 7.4, when bubbled
with 95% O2 and 5% CO2. Slices were cut from the cerebellar vermis with a moving blade microtome (DTK-1000; Dosaka
EM, Kyoto, Japan) and incubated at 30°C for ~1 hr before being
transferred to the recording chamber of a fixed-stage microscope (Axioskop-FS; Zeiss, Welwyn Garden City, UK).
Expression of recombinant GABAA receptors. Human
embryonic kidney 293 cells (HEK-293 cells; ATCC CRL 1573) were cultured
in DMEM/Ham's F-12 medium (Life Technologies, Gaithersburg, MD)
supplemented with 10% fetal bovine serum. Transfections of murine
1, 2,
3, and 2S GABAA
receptor subunit cDNAs (within a cytomegalovirus promotor-based
mammalian expression vector) were performed using a standard
electroporation procedure (Gene Electropulser II; Bio-Rad, Hercules,
CA) with 10 µg of total plasmid DNA. The subunits were tagged with
the 10 amino acid 9E10 epitope from c-myc to allow independent verification of surface expression by means of antibody staining (Connolly et al., 1996a). Receptors incorporating 9E10-tagged subunits produce GABA-activated responses, which are indistinguishable from receptors composed of wild-type subunits (Connolly et al., 1996a;
McDonald et al., 1998). Cells were co-transfected with cDNA for the
cell-surface marker protein CD8 and used for recording 24 hr after
transfection. Approximately 10 min before recording, cells were exposed
to polystyrene beads coated with an antibody to CD8 (Dynal, Great Neck,
NY) at a concentration of 1 µg/ml, allowing visual detection of
transfected cells.
Solutions and drugs. During recording, cerebellar slices and
HEK-293 cells were continuously perfused at room temperature (23-25°C) with a solution containing (in mM): NaCl 125, KCl 2.5, CaCl2 2, MgCl2 1, NaHCO3
26, NaH2PO4 1.25, glucose 25, pH 7.4 when
bubbled with 95% O2 and 5% CO2. For
whole-cell and outside-out patch recording, the pipette solution
(intracellular solution) contained (in mM): CsCl 140, NaCl
4, CaCl2 0.5, HEPES 10, EGTA 5, Mg-ATP 2, adjusted to pH
7.3 with CsOH. The following drugs were added to the external solution
as indicated: D-2-amino-5-phosphonopentanoic acid (AP5;
Tocris Cookson, Bristol, UK), bicuculline methobromide (Research
Biochemicals, Natick, MA), SR-95531 (Research Biochemicals), strychnine
(Sigma, Poole, UK), tetrodotoxin (TTX; Sigma), and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; Tocris Cookson).
Recording procedures. Standard whole-cell and outside-out
voltage-clamp recordings were made using Axopatch-1D and Axopatch-200A amplifiers (Axon Instruments, Foster City, CA). Cells were visualized with Nomarski differential interference optics (40× water-immersion objective, total magnification 320-1000×). Patch pipettes were pulled
from thick-walled borosilicate glass (GC-150F; Clark Electromedical, Pangbourne, UK), coated with Sylgard resin (Dow Corning 184), and
fire-polished to a resistance of ~10 M .
Data acquisition and analysis. Granule cell capacitance
(3.7 ± 0 0.4 pF), input resistance (9.9 ± 1.8 G), and
series resistance (39.9 ± 6.0 M) were determined in a subset
of cells (n = 14) from current transients recorded in
response to 10 mV hyperpolarizing voltage steps. These currents were
low-pass-filtered at 20 kHz ( 3 dB, eight-pole Bessel-type filter) and
digitized at 200 kHz (Intel 80486-based personal computer, Digidata
1200 interface and pCLAMP 6.1 software; Axon Instruments). In other
recordings, cell parameters were determined directly from the amplifier
settings; no series resistance compensation was used. All other data
were recorded on digital audio tape [DTR-1204; BioLogic, Claix, France (DC to 20 kHz)] with the amplifier filter (four-pole Bessel type) set
at 10 kHz.
Single-channel currents in outside-out patches.
GABA-activated single-channel currents recorded from outside-out
patches were replayed from tape filtered at 1 kHz and digitized at 10 kHz. To determine the slope conductance of the channels, recordings were made at three to five potentials between 40 and 80 mV; all-point amplitude histograms were constructed from openings at each
potential (Fetchan; pCLAMP 6.1). The mean single-channel current, determined from Gaussian fits to these amplitude
distributions, was plotted against voltage, and the data were fitted by
linear regression. In the case of multiple conductance levels within a
single patch, all current-voltage data were fitted simultaneously with
the constraint of a common reversal potential.
Individual clusters of openings, separated by at least 1 sec, were
extracted from the digitized record for further analysis. The
probability of the channel being open during each cluster (Po) was calculated according to
Po = cluster integral/(cluster length × cluster main amplitude), where the main amplitude for each cluster was
calculated from the all-point amplitude histogram (Colquhoun and Ogden,
1988; Newland et al., 1991). The baseline was taken as the mean of the
current value at the beginning and end of each cluster.
Single-channel currents were also analyzed using the method of time
course fitting (Colquhoun and Sigworth, 1995) (EKDIST; http://www.ucl.ac.uk/Pharmacology/dc.html). Currents were replayed from
tape, filtered at 2 kHz, and digitized at 20 kHz (CED 1401+ interface;
Cambridge Electronic Design, Cambridge, UK). Individual openings were
fitted by the step response function of the recording system; only
openings longer than two filter rise times (reaching 98.8% of their
full amplitude) were included. The mean amplitude levels of
single-channel currents were determined from fits of Gaussian
distributions to the cursor-fitted amplitudes. Channel open periods are
given as the weighted time constants of exponential functions fitted to
the distributions of open periods. Distributions were fitted by the
method of maximum likelihood (Colquhoun and Sigworth, 1995).
Conductance values for single-channel events are given as slope
conductance where measured, or as chord conductances (chord) at single potentials, determined
according to chord = i/(Vcmd Erev), where i is the observed
single-channel current, Vcmd the command
voltage, and Erev the reversal potential.
Erev was taken as +0.94 mV, the mean value
measured from current-voltage relationships in 13 outside-out patches
from internal granule cells.
Spontaneous IPSCs. For analysis of IPSCs, currents were
replayed from tape and filtered at 5 or 2 kHz before digitization at 40 or 10 kHz, for measurement of rise and decay times, respectively. IPSCs
were identified by eye from the digitized records and were analyzed
using software ("N" v1.0) written by Stephen Traynelis (Emory
University, Atlanta, GA). Current decays were fitted using either
"N" or Origin 4.10 (Microcal, Northampton, MA).
Nonstationary fluctuation analysis. To determine the
conductance of synaptic GABAA channels, IPSCs were analyzed
by nonstationary fluctuation analysis. To isolate fluctuations in the
current decay attributable to stochastic channel gating, the mean
waveform was scaled to the peak of individual IPSCs (Traynelis et al.,
1993; Silver et al., 1996). The requirements for such analysis include the stability of current decay time course throughout the recording and
the absence of any correlation between decay time course and peak
amplitude. The relationship between the peak-scaled variance and the
mean current is given by PS2 = i 2/NP + B2, where PS2 is the peak-scaled
variance, is the mean current, i is the weighted-mean single-channel current, NP is the
number of channels open at the peak of the IPSC, and
B2 is the background variance. In these experiments
IPSCs were analyzed from selected epochs in each of 10 cells (25-214
IPSCs) in which the peak amplitude was stable over time and in which
there was no correlation between current decay (62% decay time) and
peak amplitude (p > 0.05, Spearman rank-order
correlation test). Although the relationship between
PS2 and can be skewed if channels
open for the first time after the peak of the IPSC, meaningful values
for the weighted-mean single-channel current (i) can be
obtained by analyzing the variance of the tail of the IPSC (Traynelis
et al., 1993; Nusser et al., 1997; Traynelis and Jaramillo, 1998).
However, in this case, the PS2
relationships were parabolic, and there was no significant difference
(p = 0.69; paired Student's t test)
between the estimate of i obtained from fitting the full
parabola or its initial 50%, corresponding to the tail of the IPSC.
The values reported are those from the full fit. When pooling the
current-variance data across cells, we plotted normalized variance
(PS2 B2/Imax) against
normalized current
(/Imax), where
Imax is the peak synaptic current for each cell.
Direct resolution of synaptic channels. For analysis of
channel openings directly resolved in the IPSC decay, all-point
amplitude histograms were constructed from individual IPSCs (filtered
at 1 kHz and digitized at 5 kHz). A mixture of Gaussian distributions was fitted to the resulting histograms using a maximum likelihood fitting procedure. The amplitudes of steps in the tail of IPSCs were
calculated from the inter-peak intervals in each all-point histogram.
The presence of additional conductance states within the synaptic
channel openings was investigated using a variant of the sublevel
detection method of Patlak (1988). In this case, the digitized record
was scanned with a rolling window of 9-15 points and for all positions
of the window in which the variance was below an arbitrarily defined
limit (typically one to two times the baseline variance), median values
were calculated (Mathcad; MathSoft, Cambridge, MA) and used to
construct the amplitude histogram. All results are given as mean ± SEM. Statistical comparisons were performed with STATISTICA 5.1 (StatSoft, Tulsa OK). Differences between groups were tested using
either the Student's t test (when measures were normally
distributed; Shapiro-Wilk test) or the Mann-Whitney U test
and considered significant at p < 0.05.
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RESULTS |
Extrasynaptic GABAA receptors in internal granule cells
are heterogeneous
The single-channel properties of cerebellar granule cell
GABAA receptors have been studied previously for neurons in
culture and in slices (Kilic et al., 1993; Kaneda et al., 1995; Amico et al., 1998). Although multiple conductance states have been observed
in both preparations, it remains unclear whether the openings result
from multiple states of a single receptor type or from different
receptor types (Kaneda et al., 1995). To answer this question, we
examined currents evoked by high concentrations of GABA (in a total of
22 patches recorded from 11 different animals) that were sufficient to
induce marked receptor desensitization. Under these conditions,
GABAA receptors enter long-lived closed states, and channel
openings occur in infrequent clusters, each assumed to result from the
repeated activation of a single receptor (Sakmann et al., 1980, Hamill
et al., 1983; Colquhoun and Ogden, 1988; Newland et al., 1991).
Therefore, if different conductance states arise from different
receptor types, then their activation should give rise to distinct
cluster types.
In the presence of 10 µM AP5, 5 µM CNQX,
and 200 nM strychnine, to block NMDA, non-NMDA, and glycine
receptors, respectively, the application of 50 µM GABA to
outside-out patches from granule cells in the internal granular layer
resulted in a large inward current (Fig.
1A). In the continued
presence of GABA, the current slowly decayed until it was possible to
resolve openings and closures of single channels (Fig.
1B). Channel openings occurred in prolonged but
infrequent clusters. However, each cluster did not necessarily open to
the same main conductance state; although not always present in each
patch, three distinct cluster types were observed overall. In the
example shown in Figure 1, the openings within individual clusters were
to one of two levels, corresponding to what we term "high-conductance" and "low-conductance" events (Fig.
1C,D). Clusters of high-conductance openings were observed
in all 13 patches analyzed. These had a mean slope conductance of
27.6 ± 0.7 pS (Fig. 2). A
"mid-conductance" cluster-type, with a mean slope conductance of
16.9 ± 0.5 pS, was present in 10 of the patches. Low-conductance clusters were present in four patches and had a mean slope conductance of 11.6 ± 1.2 pS.
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Figure 1.
Activation of extrasynaptic GABAA
receptors by a high concentration of GABA evokes clusters of channel
openings. A, Application of 50 µM GABA
(solid bar) to an outside-out patch from the somatic
membrane of a P7 internal granule cell caused a large inward current
that rapidly desensitized in the continued presence of agonist (holding
potential 60 mV). B, Discrete single-channel clusters
were separated by prolonged closed periods. C, Expansion
of trace in B (open bar)
showing two types of single-channel clusters that differ in their main
conductances. D, Further expansion of
trace in C (open bars)
showing more clearly the conductance difference between the two
clusters and highlighting an apparent difference in kinetic behavior.
For display, records were filtered at 1 kHz.
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Figure 2.
Patches from somatic membrane display different
proportions of channel openings to three main conductance states.
A, Current-voltage relationships from channels in three
different patches. The left-hand panel illustrates data
from a patch that exhibited clusters of one type, giving a slope
conductance of 28 pS. The middle panel shows data from a
patch in which clusters opened to one of two current levels, giving
slope conductances of 28 and 17 pS. The right-hand panel
shows data from a third patch in which clusters exhibited openings to
one of three current levels, giving slope conductances of 26, 18, and
12 pS. B, The distribution of different cluster types
between patches. High-conductance clusters ( ) were recorded in all
13 patches and had a mean single-channel conductance of 27.6 pS, shown
by the solid line (dotted lines indicate
±1 SEM). Ten of 13 patches also contained clusters of openings that
had a mid conductance ( ; 16.9 pS). Four patches displayed clusters
of openings that had a low conductance ( ; 11.6 pS). Filled
bars indicate the four different combinations of cluster types
recorded in different patches and their relative frequency (as a
percentage).
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Patches could be divided into four groups according to the cluster
types present (Fig. 2). The majority of patches (n = 7) displayed high- and mid-conductance cluster types, three patches contained all three cluster types, and two patches exhibited only high-conductance clusters, whereas high- and low-conductance clusters were seen in only one patch (Fig. 2B). Although the
total length of recording for each patch differed (~1-15 min), the
likelihood of observing clusters of different conductance within a
given patch did not reflect any underlying difference in the frequency of opening. Thus, when present, the various cluster types occurred with
similar mean frequencies (~0.06, 0.05, and 0.05 Hz, for high-, mid-,
and low-conductance clusters, respectively).
To test for the presence of channel subconductance states within
clusters and to determine any kinetic differences between the three
cluster types, we reexamined clusters of openings by the method of time
course fitting (Colquhoun and Sigworth, 1995). This approach revealed
that high-conductance clusters (n = 9 patches) contained openings with a main chord conductance of 28.5 ± 0.8 pS
and a subconductance state of 17.4 ± 1.0 pS. This lower
conductance state was present in each cluster and accounted for a
consistent but relatively minor fraction of openings (10.1 ± 2.6%). In all patches tested, direct transitions were observed between
the main and lower conductance states. Time course fitting of the
mid-conductance clusters (main state 19.9 ± 1.9 pS;
n = 4) also revealed a subconductance of 10.6 pS in two
patches (11.2% of openings). Low-conductance clusters were analyzed in
five patches and had a single-channel conductance of 14.4 ± 0.4 pS, with no apparent subconductance states. In some recordings,
high-conductance clusters appeared to display briefer openings than the
mid- or low-conductance clusters (Fig. 1D). Indeed,
time course fitting revealed shorter contiguous open periods in the
high-conductance clusters (5.2 ± 0.9 msec) compared with the mid-
(6.5 ± 1.2 msec) and low-conductance clusters (9.9 ± 2.9 msec). This difference between high- and low-conductance openings was
significant (p < 0.05, Mann-Whitney
U test). Together, the subconductance and open period data
emphasize the different properties of the three cluster types.
To examine the variation between clusters, we next studied all clusters
individually, measuring both the main cluster conductance and the
proportion of time for which the channel was open during a cluster
(Po) (Colquhoun and Ogden, 1988; Newland
et al., 1991). The main conductance state for individual clusters was
obtained from the largest Gaussian component in fits to individual
all-point histograms and Po values calculated
after the integration of each cluster (see Materials and Methods). The
clusters illustrated in Figure
3A are from a single patch
that exhibited all three cluster types. The distribution of these three
clusters among the entire sample is shown by the symbols in Figure
3B. As shown in Figure 3C, the high-conductance
clusters exhibited a lower mean Po than the mid-
and low-conductance clusters. The Po calculated for 224 high-conductance clusters (chord conductance 27.9 ± 2.7 pS) was 0.6 ± 0.2, whereas the mid-conductance (16.7 ± 1.6 pS, n = 92) and low-conductance (11.7 ± 1.5 pS,
n = 37) clusters had identical
Po values of 0.8 ± 0.1. The
Po value for high-conductance clusters was
significantly lower that those for mid- and low-conductance clusters
(p < 0.05, Mann-Whitney U
test).
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Figure 3.
Extrasynaptic receptors exhibit channel clusters
that fall into distinct classes with different main conductance states
and open probabilities. A, Examples of high-, mid-, and
low-conductance channel clusters recorded from a single somatic patch
from a P7 internal granule cell (60 mV; for display, records were
filtered at 1 kHz). The integral is plotted below each
current record. Shown to the right of each cluster is
its corresponding all-point amplitude histogram with the calculated
chord conductance and Po (see Materials and
Methods). B, The distribution of all chord-conductance
estimates from 310 individual clusters recorded from a total of 21 patches. The histogram was fitted with the sum of three Gaussian
distributions, with peaks at 12, 17, and 28 pS (compare with the slope
conductance estimates in Fig. 2). The symbols
superimposed on the distribution indicate the conductance for each of
the three clusters shown in A. C, The relationship
between cluster main conductance and cluster
Po. The distinction between low-conductance
(), mid-conductance (), and high-conductance clusters () is
based on the distribution in B and calculated by the
method of minimum misclassification (Colquhoun and Sigworth, 1995).
Superimposed bars indicate the mean and SD of main
conductance and Po for each cluster
type.
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Multiple receptor types are present before synapse formation
One interpretation of these observations is that the clusters of
openings represent activity of individual channels and the different
types of clusters arise from three or more distinct receptor types with
different main conductance states. Granule cells at P7 are in the early
stages of synapse formation. GABA-positive Golgi axon terminals are
first seen in the internal granular layer at P2-P3 (Meinecke and
Rakic, 1990), whereas spontaneous IPSCs can be recorded at P4 and are
present in ~70-80% of cells by P7 (Brickley et al., 1996; this
study). The heterogeneous properties of GABAA channels that
we observe at this age could therefore reflect developmental
differences between cells. Indeed, it has been suggested that
activation of GABAA receptors themselves, for example after
synaptogenesis, may be responsible for triggering the expression of
different GABAA receptor types (for review, see Carlson et
al., 1998). To examine the properties of GABAA receptors
before synapse formation, we recorded from premigratory cells in the
external granule cell layer at P7. In patches from these cells there
were also three distinct cluster types, similar to those present in
postmigratory granule cells. Clusters of high-conductance openings
(chord conductance 25.2 ± 0.9 pS) were observed in eight of nine
patches examined, mid-conductance clusters (17.0 ± 0.6 pS) were
present in four patches, and low-conductance clusters (12.2 ± 1.4 pS) were present in three patches. A single patch contained clusters of
the mid-conductance type (17 pS) alone and lacked any high-conductance
clusters. These results suggest, therefore, that heterogeneity of
channel conductance is not solely the result of developmental
differences between cells.
The simplest explanation for our observations is that the three
different cluster types arise from distinct receptor types that differ
in their main conductance states. It is also possible, however, that
all openings arise from a single receptor type that undergoes some form
of "modal" gating to preferred conductance states that are
segregated within different clusters. However, intracellular modulation
of GABAA receptor activity, for example by phosphorylation,
is known to influence channel kinetics but does not affect
single-channel conductance (Jones and Westbrook, 1997; Amico et al.,
1998). The variable frequency of occurrence of different cluster types
between patches also argues against the possibility that a single
receptor type is responsible for all three cluster types. However, we
tested this possibility further by recording from a homogenous
population of GABAA receptors in HEK-293 cells. These were
transiently transfected with 1,
2, and 2S subunits, which, given
their preferential coassembly, are thought to form only a single type
of GABAA receptor (Angelotti and Macdonald, 1993; Tretter
et al., 1997). If each cluster type in granule cells reflects a
different "mode" of the same receptor rather than different
receptors, then one might also expect to record clusters with different
main conductance states from a "pure" receptor population.
Recombinant GABAA receptors
When patches from HEK-293 cells expressing
1, 2, and 2S
subunits were initially exposed to 50 µM GABA, a large
inward current was elicited that rapidly declined until single-channel
openings could be observed. This pattern of activity was broadly
similar to that seen with native receptors, and the overall cluster
frequency (0.17 ± 0.03 Hz, n = 12; after four
separate transfections) was not significantly different from that
observed in patches from internal granule cells (0.11 ± 0.02 Hz,
n = 17; p > 0.05, unpaired Student's
t test). However, unlike native receptors, each cluster of
openings from recombinant receptors appeared to be to the same main
conductance state (compare Fig.
4A with
1B).
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Figure 4.
Recombinant
122S receptors exhibit a
single type of channel cluster. A, Clusters of channel
openings recorded in an outside-out patch from an HEK-293 cell
transiently transfected with 1,
2, and 2S subunits in the
continued presence of 50 µM GABA (60 mV). All clusters
contain high-conductance openings. B, An individual
cluster recorded from the same patch. Inset shows an
expanded view of part of the cluster (solid bar)
illustrating the presence of clear sub-level transitions (for display,
records were filtered at 1 kHz). The dotted lines
indicate the closed, sub, and main conductance states, as determined
from fits to an all-point histogram constructed for this patch (data
not shown). C, The distribution of all chord-conductance
estimates (main conductance) from 190 individual clusters recorded from
a total of 13 patches. Most of the clusters are of the high-conductance
type such that a single Gaussian adequately describes this
distribution. Five cluster measurements lay outside the single Gaussian
distribution. In three of these, high-conductance openings were present
within the clusters, but most of the openings were to the
subconductance state. D, The relationship between the
cluster main conductance and the cluster Po
suggests the existence of a single main population of cluster types for
this recombinant GABAA receptor.
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In 13 patches a sufficient number of clusters was recorded to allow
construction of all-point amplitude histograms, yielding a main chord
conductance of 25.9 ± 0.3 pS. Clear transitions to a lower
conductance state were also evident during these high-conductance clusters (Fig. 4B). In four patches this
subconductance state was sufficiently frequent to be discernible from
the all-point amplitude histograms (data not shown), giving a
conductance of 14.6 ± 1.1 pS. We next analyzed each cluster
independently (as for native receptors; see above). For 190 clusters
from 13 patches, the main conductance state (the largest component of
the all-point histogram) was 27.9 ± 0.2 pS, and the
Po value was 0.50 ± 0.01 (n = 190 clusters). These values were similar to those
for the native high-conductance clusters (compare Fig. 4C,D
with Fig. 3B,C).
This relatively simple channel behavior was also seen with a second
combination of subunits. Thus, when a transfection was performed with a
3 subunit rather than the 2 subunit, the
resulting receptors also gave rise to clusters of an apparently uniform type, with a main single-channel conductance of 28.0 ± 1.0 pS, a
subconductance state of 17.4 ± 1.9 pS (n = 4),
and a Po of 0.40 ± 0.02 (89 clusters). In
agreement with the impression of uniform cluster type for both
122S and
132S receptors, 286 of the 289 clusters analyzed (~99%) contained openings to the
high-conductance state (Fig. 4). This is clearly different from the
situation in native receptors (internal granule cells) where 107 of 310 clusters (35%) were of a mid- or low-conductance type.
Taken together, these results support the idea that, for native
receptors, clusters of openings with different main conductance states
represent the activity of different receptor types, each having a
distinct main conductance and, in the case of high- and mid-conductance
types at least, a less frequently occurring subconductance state.
Because recombinant GABAA receptors containing different subunits can give rise to channels with similar conductances (see above) (Macdonald and Olsen, 1994), each cluster type seen in granule
cells could arise from receptors with several molecular compositions.
Thus, we conclude that at least three receptor types are
present in the somatic membrane of both premigratory and postmigratory granule cells. Given this diversity of extrasynaptic receptors, we next
asked whether such diversity occurred at the synapse.
GABAA receptor-mediated IPSCs in cerebellar
granule cells
In the presence of 5 µM CNQX and 10 µM
AP5, >70% of cells (86/110, from 34 animals) exhibited spontaneous
IPSCs (Fig. 5A). The reversal
potential for IPSCs (+8.4 ± 0.6 mV, n = 10) was
close to the expected Cl ion equilibrium potential
of +2 mV given the near symmetrical Cl ion
distribution. The IPSCs were reversibly blocked by the competitive GABAA receptor antagonists bicuculline methobromide (10 µM) and SR-95531 (100 nM) but were unaffected
by the glycine receptor antagonist strychnine (200 nM)
(data not shown) (Kaneda et al., 1995). As previously reported, the
IPSCs were greatly reduced in frequency by 200 nM
tetrodotoxin (from ~1 Hz to <0.1 Hz), indicating that most events
result from action potentials in presynaptic Golgi cells (Kaneda et
al., 1995; Brickley et al., 1996; Rossi and Hamann, 1998).
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Figure 5.
Spontaneous IPSCs display a rapid rise and slow,
multi-exponential decay. A, Continuous record showing
spontaneous IPSCs recorded from a P7 internal granule cell in the
presence of 5 µM CNQX, 10 µM AP5, and 200 nM strychnine (70 mV; 2 kHz filtering). B,
The initial phase of some IPSCs shows obvious inflections caused by
superimposition of events (asterisks; 5 kHz filtering).
C, Most IPSCs exhibit monotonic rises with no obvious
inflections. Only IPSCs that exhibited such a monotonic rise were
included in any further analysis. D, The distribution of
the resulting 10-90% rise times is well described by a single
Gaussian. The inset illustrates the lack of relationship
between rise time and peak amplitude for IPSCs recorded in one cell.
E, An example of an averaged IPSC with its decay fitted
by the sum (solid line) of three exponentials
(dotted lines). The inset shows the
average waveform (dots) and single
(1), double (2), or triple
(3) exponential fits (solid lines)
displayed with current on a log scale; only the triple exponential fit
adequately describes the current decay (2 kHz filtering).
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For each cell, an average IPSC waveform was generated from >50 events
aligned on their rising phase. Superimposed events were excluded from
analysis, and we included only those IPSCs that had a monotonic rising
phase lacking inflections (Fig. 5B,C) and that returned to
baseline without contamination from subsequent events. As expected from
the electrically compact nature of the granule cell (Silver et al.,
1992; Clark et al., 1997), the majority of IPSCs had a rapid rising
phase (Fig. 5C) with a 10-90% rise time that was not
correlated with peak amplitude (Fig. 5D). The average IPSC
waveforms from 14 cells had a 10-90% rise time of 372 ± 19 µsec and a decay best described by the sum of three exponentials ( 1 = 8.0 ± 1.1 msec, 22%; 2 = 33.5 ± 2.4 msec, 58%; 3 = 102.9 ± 8.2 msec)
(Fig. 5E).
Single-channel properties of synaptic GABAA receptors
estimated from fluctuation analysis
To obtain an estimate of the single-channel conductance for
receptors underlying the IPSC we used the method of peak-scaled nonstationary fluctuation analysis (Traynelis et al., 1993; DeKoninck and Mody, 1994; Silver et al., 1996; Traynelis and Jaramello, 1998).
This approach enables channel conductance to be determined from the
variance of individual synaptic events about the mean synaptic
waveform. For each of 10 cells, the mean waveform was scaled to the
peak of each IPSC, and the mean current and its variance were
determined for 30 bins of equal amplitude (Fig. 6A). In all cases,
plotting the mean current against the variance yielded a characteristic
parabolic relationship. For the example shown in Figure
6B, fitting the current-variance relationship (see
Materials and Methods) gave a weighted-mean single-channel current of
1.60 pA (corresponding to a chord conductance of 22.5 pS) and a mean of
39 channels open at the peak of the IPSC. The single-channel current
values from 10 cells were normally distributed (Shapiro-Wilk test),
with a mean of 1.96 ± 0.13 pA, corresponding to a conductance of
27.6 ± 1.8 pS (Fig. 6C). Plotting the normalized variance against the normalized current (see Materials and Methods) for
data pooled from all 10 cells confirmed the almost perfect parabolic
relationship between mean current and variance (Fig. 6D), suggesting that the weighted-mean conductance is
the same for channels contributing to different phases of the IPSC
decay.
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Figure 6.
Peak-scaled nonstationary fluctuation analysis of
IPSCs reveals uniform weighted-mean single-channel conductance of
synaptic receptors. A, The average waveform of 74 IPSCs
(solid line) is shown scaled to the peak of an
individual IPSC (gray line; 2 kHz filtering). The
horizontal dotted lines represent the 30 amplitude bins
used to determine values of mean current and variance.
B, A plot of mean current against variance for the cell
shown in A. The plot is fitted with a parabolic
relationship to give the weighted-mean single-channel current
(i; also given as conductance, ) and the number of
channels open at the peak (Np). The
dotted line indicates the baseline variance.
C, Histogram of weighted-mean single-channel current
obtained from a total of 10 cells illustrating the uniform distribution
of conductance. D, A plot of normalized current against
normalized variance with data pooled from all 10 cells (error bars
represent SEM).
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Direct resolution of synaptic channel events
In the most favorable whole-cell recordings (baseline
current-variance <330 fA2; mean 252 ± 22 fA2; n = 8; 1 kHz filter), the high
input resistance and electrical compactness of cerebellar granule cells
allowed us to resolve individual channel closures in the tail of IPSCs.
This is illustrated in Figure
7A, which shows successive
enlargements of the tail of an individual IPSC. For each of eight cells
examined, channel-like steps could be clearly identified in the decay
phase of all IPSCs, regardless of the IPSC peak amplitude (Fig.
7B). Moreover, for each of the smallest IPSCs observed,
their peak was an integer multiple of the last resolvable current step.
For example, in the case of the two IPSCs shown in Figure
7C, the waveforms could be divided into five and seven steps
of equal amplitude.
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Figure 7.
Unitary current steps can be resolved in the decay
of spontaneous IPSCs. A, Successive enlargements
(solid bars) of the decay phase of a spontaneous IPSC
recorded from a P7 internal granule cell (70 mV). The second
enlargement clearly shows the stepped nature of the IPSC decay (the
equally spaced dashed lines illustrate the approximate
amplitude levels of the steps). B, Four representative
IPSCs showing the consistent presence of a channel-like step at the end
of each IPSC. The peaks of the IPSCs have been truncated for display,
and the dotted line indicates the pre-event baseline
current. C, Two selected IPSCs, representative of the
smallest events recorded. In each case the peak amplitude is an integer
multiple (5 and 7) of the last step amplitude (dotted
lines). For display, records were filtered at 1 kHz.
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To quantify the size of the current steps, all-point amplitude
histograms were constructed from individual IPSCs (Borst et al., 1994).
For the IPSC shown in Figure
8A, this revealed a
series of six equally spaced peaks (inset). The first peak
in the histogram corresponds to the closed level (C),
and the five subsequent peaks result from steps in the tail of the
IPSC. The histogram was fitted with the sum of six Gaussian
distributions, and step sizes were determined from the inter-peak
intervals (1.7, 2.2, 1.9, 1.8, and 2.1 pA). In the cell from which this
IPSC was recorded, the average step size determined from 47 steps in 27 individual IPSCs was 2.04 ± 0.04 pA, corresponding to a
single-channel chord conductance of 28.7 pS. The amplitude of these
steps appeared consistent within individual IPSCs. Furthermore, the
step size was consistent for different IPSCs in the same cell and for
IPSCs in different cells. Figure 8B shows data from
one cell in which the step size for the final two resolvable closures
(S1 and S2) was determined for 50 consecutive IPSCs. Because these
spontaneous IPSCs arise from an unknown number of different synapses,
it is clear that the conductance of the underlying receptors is similar
not only at individual synapses but also at different synapses on the
same cell. As is also apparent from Figure 8B, the
amplitudes of the last five steps (S1-S5) determined
from all events were remarkably consistent. Finally, as shown in Figure
8C, the IPSC step size (calculated as a single
value for each IPSC; taking a mean value when multiple steps were
resolved) was normally distributed, with a low coefficient of variation
(CV) (mean 1.87 ± 0.02 pA, n = 234 IPSCs,
corresponding to a conductance of 26.4 pS; CV = 0.13). A similar
distribution (data not shown) was obtained when all resolved steps
(n = 480) were considered individually and had a CV of
0.17.
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Figure 8.
Analysis of resolvable current steps in IPSCs
reveals a uniform single-channel conductance and a rare lower
conductance state. A, Quantitative analysis of a stepped
IPSC waveform recorded from a P7 internal granule cell (1 kHz
filtering). The IPSC has five steps in its decay, seen as clearly
resolved peaks in its all-point amplitude histogram
(inset). The positions of the baseline
(C) and the numbered dashed lines
(1-5) are taken from the fit of six Gaussian components
to the amplitude histogram. B, Plots of the inter-peak
step size for the last two steps (S1 and
S2) calculated for 50 consecutive IPSCs recorded in the
same cell as A. The bottom panel
illustrates the consistency of the step size for the last five channel
closures (S1-S5) recorded from a total of eight cells.
The mean step sizes (open symbols) and the SD are
plotted for each step. The dotted line shows the mean
value for S1. C, A histogram of IPSC step
size (calculated as a single value for each of 234 IPSCs
recorded from 8 cells) fitted with a single Gaussian. D,
A single IPSC in which different sized steps were observed in the decay
(1 kHz filtering). The inset was obtained after
smoothing of the trace (see Materials and Methods) to better illustrate
the steps in the waveform. The dotted lines superimposed
on the trace show current levels obtained from peaks of the fit to the
all-point histogram. C indicates the final closed state,
and the dashed lines 1-3 represent the values of the
three open levels observed in the decay. The final step size was
calculated from the inter-peak interval between C and
2, and the preceding smaller step size was calculated
between C and 1.
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Together these observations suggest that GABAA receptors in
the synaptic membrane of granule cells have a uniform single-channel conductance, similar to the high-conductance channels identified in the
extrasynaptic membrane. As noted above, one feature of the
high-conductance extrasynaptic receptors is the occasional presence of
a subconductance state. If synaptic receptors are similar to these
extrasynaptic receptors, then they too might be expected to display a
subconductance state. Indeed, in a small number of IPSCs, channel
openings of an apparently lower conductance were detected in
conjunction with the high-conductance events. To increase the
resolution of channel openings and minimize the contribution of
background noise, we applied a smoothing procedure to these selected
IPSCs (see Materials and Methods). This confirmed that a very small
proportion of resolvable synaptic channel openings (~2%; 9 out of
the total of 480) were to a distinct lower conductance level. One
particularly clear example is illustrated in Figure 8D. In the tail of this IPSC it is possible to
discern a prolonged opening of lower amplitude before the final
full-amplitude channel closure. This is made clearer in the smoothed
waveform and its associated amplitude histogram (Fig.
8D, insets). Openings of this type could
be resolved in nine IPSCs and had a mean amplitude of 1.07 ± 0.06 pA (15.1 pS), significantly lower (p < 0.05, paired Student's t test) than the main conductance state
determined in the same IPSCs (1.78 ± 0.06 pA; 25.1 pS). The
temporal resolution afforded by whole-cell recordings makes it
difficult to say whether these openings represent true subconductance
states or whether this lower level results from the opening of a
separate mid-conductance GABAA receptor. Regardless of its
origins, the lower conductance state contributes very little to total
charge transfer during a single IPSC.
Finally, it is interesting to note that individual channel openings as
well as the more obvious channel closures could also be seen during the
IPSC decay (Figs. 7C, 8A). The lack of
skew in the parabolic current-variance relationship (Fig. 6) suggests that few, if any, channels open for the first time after the peak of
the IPSC (Traynelis et al., 1993). It would thus appear that these
events reflect the reopening of GABAA receptors
after their synchronous opening at the peak of the synaptic current.
This delayed reopening is thought to occur on exit from desensitized states, entered after the brief exposure to high concentrations of
transmitter in the cleft, and has been suggested to prolong the decay
of the IPSC (Jones and Westbrook, 1995).
| |
DISCUSSION |
In this study, we have examined the single-channel properties of
synaptic and extrasynaptic GABAA receptors in developing cerebellar granule cells. On the basis of differences in channel conductance, we suggest that GABAA receptors in
premigratory granule cells before synapse formation are heterogeneous,
with at least three receptor types present. This heterogeneity is
maintained in granule cells that have recently migrated and whose
extrasynaptic GABAA receptors display very similar
properties. By contrast, receptors at newly formed synapses open,
almost exclusively, to a single, high-conductance state.
Subunit diversity and channel heterogeneity
In granule cells the pattern of GABAA receptor subunit
expression is developmentally regulated. In situ
hybridization studies have shown that premigratory cells express
2, 3,
3, 1, and 2
subunit mRNA (Laurie et al., 1992). After migration, levels of
2, 3, and 1
mRNA decline, whereas levels of 1 and 2
mRNA increase dramatically. After the first postnatal week,
6 and subunit expression become significant (Laurie
et al., 1992; Jones et al., 1997), leading to the predominance of
1, 6,
2, 3,
2, and subunit mRNAs in the adult.
Immunohistochemical studies of adult tissue have confirmed the presence
of the corresponding proteins (Zimprich et al., 1991; Fritschy et al.,
1992; Nusser et al., 1998), and a combination of techniques have
suggested that at least four receptor types may be present
(12/32,
62/32, 62/3, and
162/32)
(Nusser et al., 1998). At the age we have examined (P7) it is likely
that 6 and proteins are not yet expressed;
nevertheless, multiple , , and subunits will be present. Thus
the potential for receptor heterogeneity exists at all stages of
granule cell development (for review, see Wisden et al., 1996; Carlson
et al., 1998).
How does this subunit diversity relate to the heterogeneity of channel
conductance? The ion selectivity and conductance of GABAA
receptors is determined by the presence of charged residues close to
and within the second transmembrane domain (TM2) of each subunit (Smith
and Olsen, 1995). To assess the possible influence of different
subunits on single-channel conductance, the primary structure of
GABAA receptor subunits was compared, and the net charge
for the region encompassing TM2 (between the intracellular end of TM1
and the extracellular end of TM3) was calculated for all , , ,
and subunits [after the approach of Fisher and Macdonald (1997)].
The and subunits contribute a greater net positive charge
(1, 2, +4;
3 +5) to this region than do any of the or subunits (+3 and +2, respectively). It has been suggested (Fisher and
Macdonald, 1997) that this difference may account for the consistent
observation of a higher main conductance state for or
combinations when compared directly with heterodimers
(26-32 pS vs 11-20 pS) (Puia et al., 1990; Verdoorn et al., 1990;
Angelotti and Macdonald, 1993; Fisher and Macdonald, 1997; S. Brickley
and M. Farrant, unpublished observations). Our single-channel
conductance data indicate the presence of at least three different
receptor types in granule cells at P7. Although we cannot equate the
high-, mid-, and low-conductance channels (28, 17, and 12 pS) with
specific subunit combinations, it seems likely that at P7 the
high-conductance openings result from receptors composed of , ,
and subunits, whereas the lower conductance events result from
receptors lacking a subunit. The significantly lower
Po values and briefer open periods of the
high-conductance clusters further distinguish these receptors from
those giving rise to clusters of lower conductance openings.
Not only does the subunit influence channel conductance, but it is
also essential for allosteric modulation by benzodiazepines (for
review, see Barnard et al., 1998). Consistent with the presence of
-containing receptors, GABA-induced currents in premigratory and
postmigratory granule cells (Farrant et al., 1995), as well as those in
cultured granule cells (Mathews et al., 1994; Mellor and Randall,
1997), are potentiated by benzodiazepines. Most neurons express subunits, and heteromeric assemblies of , , and subunits are
considered to be the most common form of native GABAA receptor (McKernan and Whiting, 1996). Nevertheless, it is clear that,
in expression systems at least, combinations of and subunits
can form functional receptors (Connolly et al., 1996a,b; Gorrie et al.,
1997; Tretter et al., 1997). However, because of evidence for
preferential coassembly of , , and subunits (Angelotti and
Macdonald, 1993; Tretter et al., 1997), the possible existence of
native receptors formed from and subunits has been largely overlooked. Our data, showing the presence of both low- and
high-conductance receptors in developing cerebellar granule cells,
suggests an ability of neurons to independently assemble either -
or -containing receptors. Moreover, these receptors appear to
be targeted to different regions of the neuronal membrane.
Targeting of GABAA receptors
At least three receptor types are present in the extrasynaptic
membrane of granule cells, but only a high-conductance type is found at
the synapse. The conductance of synaptically activated GABAA receptors was calculated by peak-scaled nonstationary
fluctuation analysis and from direct resolution of channel closures in
the tail of IPSCs. For several reasons, we believe that the synaptic channel is of a single type. There was a remarkable correspondence between the weighted-mean single-channel conductance obtained with
fluctuation analysis and the unitary conductance determined from
directly resolved channel openings. Moreover, the parabolic relationship between mean current and variance indicates that there is
no difference in the weighted-mean conductance of channels contributing
to different phases of the IPSC decay. This was supported by the
consistency of step size throughout the IPSC and by the fact that the
smallest IPSCs had peak amplitudes that were integer multiples of the
unitary step size. It is important to note that a single conductance
state does not establish the presence of a single GABAA
receptor population. In studies of recombinant receptors, all
combinations examined so far give rise to similar high-conductance
channels. For example, in this study, the substitution of a
3 for a 2 subunit did not significantly
alter single-channel conductance. Nevertheless, the high conductance of
the synaptic receptors (Table 1) clearly
indicates that they contain a subunit. This conclusion is supported
by the fact that IPSCs at P7 are prolonged by benzodiazepines (Farrant
and Brickley, unpublished observation) in a manner similar to that
reported for granule cells in slightly older animals (Rossi and Haman,
1998).
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Table 1.
Single-channel chord conductance values for synaptic and
extrasynaptic GABAA receptors in internal granule cells at
P7
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Potential mechanisms of receptor targeting
It has been known for some time that the subunits are
concentrated at many GABAA synapses (Somogyi et al., 1996).
The most novel aspect of our results is the suggestion that
GABAA receptors lacking a subunit are specifically
excluded from the synapse. In this context it is interesting
to note that in adult granule cells the subunit is found in both
synaptic and extrasynaptic membrane, whereas the subunit, which is
thought to substitute for the in some heteromeric assemblies, is
found only extrasynaptically (Nusser et al., 1998). Recently, several
mechanisms have been identified that may account for the differential
targeting of receptors containing a subunit. A novel
microtubule-associated protein GABARAP
(GABAA-receptor-associated protein) has been identified and
shown to interact preferentially with the 2 subunit,
linking it to the cytoskeleton and promoting receptor clustering (Wang et al., 1999). The protein gephyrin has also been implicated in the
clustering of GABAA receptors at synaptic sites (Craig et al., 1996; Giustetto et al., 1998), and in neurons from mice lacking the 2 subunit, both GABAA receptor and
gephyrin clusters are disrupted (Essrich et al., 1998). Whether either
of these interactions accounts for the preferential incorporation of
-containing receptors at granule cell synapses remains to be determined.
Although differential targeting of receptors is an attractive
explanation for our observations, other interpretations of the data
need to be considered. Recent studies suggest that the conductance of
certain ligand-gated ion channels may be influenced by agonist concentration (Eghbali et al., 1998; Rosenmund et al., 1998). If this
were the case, the difference in conductance of extrasynaptic and
synaptic GABAA receptors could simply reflect the
difference between steady-state activation of receptors in the presence
of 50 µM GABA and the activation of synaptic receptors by
a brief pulse of transmitter of much higher concentration. We think
this is unlikely. Brief application (1 msec) of 1 mM GABA
to outside-out patches from internal granule cells (P7) results in the
activation of GABAA receptors with a range of conductances
similar to those seen in the present steady-state experiments (our
unpublished observation). As in the steady-state experiments, most of
the openings are of a high-conductance type (~30 pS), but lower
conductance openings are also present. Moreover, channels activated by
low micromolar concentrations of GABA also display similar conductances (Kaneda et al., 1995; Amico et al., 1998). Thus, for GABAA
receptors in cerebellar granule cells at least, the concentration of
transmitter does not affect single-channel conductance. Because our
experiments identify only functional receptors, we cannot of course
exclude the possibility that multiple receptor types are present in the postsynaptic membrane, with a specific subset being nonfunctional or
"silent" (Lewis et al., 1990; Poisbeau et al., 1997).
Functional consequences of differential receptor localization
Although granule cells receive synaptic input only on their distal
dendrites, most of the GABAA receptor subunits are
localized to proximal dendritic and somatic membrane (Nusser et al.,
1995). The significance of these extrasynaptic GABAA
receptors remains unclear. However, in older animals, extrasynaptic
62/32 or 62/3 GABAA receptors may
be involved in generating a tonic conductance attributable to their
activation after spillover of GABA from the synaptic cleft (Kaneda et
al., 1995; Brickley et al., 1996; Tia et al., 1996; Wall and Usowicz,
1997; Nusser et al., 1998; Rossi and Haman, 1998). More speculatively,
in immature cells the extrasynaptic receptors could be important in
some aspects of the migration and differentiation of cerebellar granule
cells. The depolarizing action of GABA in developing cerebellar granule cells (Brickley et al., 1996) could underlie possible trophic roles for
this transmitter system that precede its more conventional inhibitory
actions (Carlson et al., 1998).
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FOOTNOTES |
Received Nov. 5, 1998; revised Feb. 3, 1999; accepted Feb. 5, 1999.
This research was supported by the Wellcome Trust and the Medical
Research Council. We thank Stephen Traynelis, David Colquhoun, and
Ioana Vais for providing software; Christopher Connolly, Bernie McDonald, and Stephen Moss for providing GABAA subunit
clones and transfected HEK-293 cells; and Michael Häusser, Zoltan
Nusser, Angus Silver, Geoff Swanson, and David Wyllie for comments on this manuscript.
Correspondence should be addressed to Dr. Mark Farrant, Department of
Pharmacology, University College London, Gower Street, London WC1E 6BT, UK.
| |
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A. L. Scotti and H. Reuter
Synaptic and extrasynaptic gamma -aminobutyric acid type A receptor clusters in rat hippocampal cultures during development
PNAS,
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[Abstract]
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B. J Krishek and T. G Smart
Proton sensitivity of rat cerebellar granule cell GABAA receptors: dependence on neuronal development
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[Abstract]
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M. Orchinik, S. S. Carroll, Y.-H. Li, B. S. McEwen, and N. G. Weiland
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[Abstract]
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M. B. Kennedy
Sticking together
PNAS,
October 10, 2000;
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[Full Text]
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L. Chen, H. Wang, S. Vicini, and R. W. Olsen
The gamma -aminobutyric acid type A (GABAA) receptor-associated protein (GABARAP) promotes GABAA receptor clustering and modulates the channel kinetics
PNAS,
September 8, 2000;
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190133497.
[Abstract]
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M. Lorez, D. Benke, B. Luscher, H. Mohler, and J. A Benson
Single-channel properties of neuronal GABAA receptors from mice lacking the {gamma}2 subunit
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[Abstract]
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U. Kraushaar and P. Jonas
Efficacy and Stability of Quantal GABA Release at a Hippocampal Interneuron-Principal Neuron Synapse
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C. Misra, S. G Brickley, D. J A Wyllie, and S. G Cull-Candy
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[Abstract]
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W. Shen, S. Mennerick, D. F. Covey, and C. F. Zorumski
Pregnenolone Sulfate Modulates Inhibitory Synaptic Transmission by Enhancing GABAA Receptor Desensitization
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A. Momiyama
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M. I. Banks and R. A. Pearce
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[Abstract]
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M. M. Huntsman and J. R. Huguenard
Nucleus-Specific Differences in GABAA-Receptor-Mediated Inhibition Are Enhanced During Thalamic Development
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[Abstract]
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C. N. Connolly, J. T. Kittler, P. Thomas, J. M. Uren, N. J. Brandon, T. G. Smart, and S. J. Moss
Cell Surface Stability of gamma -Aminobutyric Acid Type A Receptors. DEPENDENCE ON PROTEIN KINASE C ACTIVITY AND SUBUNIT COMPOSITION
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[Abstract]
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D. Bai, P. S. Pennefather, J. F. MacDonald, and B. A. Orser
The General Anesthetic Propofol Slows Deactivation and Desensitization of GABAA Receptors
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[Abstract]
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Z. Nusser, W. Sieghart, and I. Mody
Differential regulation of synaptic GABAA receptors by cAMP-dependent protein kinase in mouse cerebellar and olfactory bulb neurones
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[Abstract]
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K. Baer, C. Essrich, J. A. Benson, D. Benke, H. Bluethmann, J.-M. Fritschy, and B. Luscher
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PNAS,
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[Abstract]
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A. L. Scotti and H. Reuter
Synaptic and extrasynaptic gamma -aminobutyric acid type A receptor clusters in rat hippocampal cultures during development
PNAS,
March 13, 2001;
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[Abstract]
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L. Chen, H. Wang, S. Vicini, and R. W. Olsen
From the Cover: The gamma -aminobutyric acid type A (GABAA) receptor-associated protein (GABARAP) promotes GABAA receptor clustering and modulates the channel kinetics
PNAS,
October 10, 2000;
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[Abstract]
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TOP
ABSTRACT
INTRODUCTION
