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The Journal of Neuroscience, June 15, 2002, 22(12):4805-4813
GABAergic Terminals Are Required for Postsynaptic Clustering of
Dystrophin But Not of GABAA Receptors and Gephyrin
Ina
Brünig1,
Anthi
Suter1,
Irene
Knuesel1,
Bernhard
Lüscher2, and
Jean-Marc
Fritschy1
1 Institute of Pharmacology and Toxicology, University
of Zurich, CH-8057 Zurich, Switzerland, and 2 Department of
Biology and Department of Biochemistry and Molecular Biology,
Pennsylvania State University, University Park, Pennsylvania 16802
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ABSTRACT |
In rat hippocampal cultures, we show by multilabeling
immunocytochemistry that pyramidal cells, which receive little or no GABAergic input, mistarget  2-GABAA receptors
and gephyrin to glutamatergic terminals. This mismatch does not occur
in neurons innervated by numerous GABAergic terminals. A similar
phenomenon has been reported for isolated autaptic hippocampal neurons
(Rao et al., 2000 ). GABAergic synapses typically form multiple release sites apposed to GABAA receptor and gephyrin clusters.
Remarkably, dystrophin, a protein highly abundant in skeletal muscle
membranes, is extensively colocalized with
2-GABAA receptors exclusively opposite
GABAergic terminals. In addition, selective apposition of syntrophin
and  -dystroglycan to GABAergic presynaptic terminals suggests that
the entire dystrophin-associated protein complex (DPC) clusters at
GABAergic synapses. In contrast to gephyrin and GABAA
receptors, DPC proteins are not mistargeted to glutamatergic synapses,
indicating independent clustering mechanisms. This was confirmed in
hippocampal neurons cultured from GABAA receptor  2 subunit-deficient mice. Clustering of
GABAA receptor and gephyrin in these neurons was strongly
impaired, whereas clustering of dystrophin and associated proteins was
unaffected by the absence of the 2 subunit. Our results
indicate that accumulation of dystrophin and DPC proteins at GABAergic
synapses occurs independently of postsynaptic GABAA
receptors and gephyrin. We suggest that selective signaling from
GABAergic terminals contributes to postsynaptic clustering of dystrophin.
Key words:
GABAergic synapse; dystrophin; dystrophin-associated
protein complex; presynaptic signaling; clustering; hippocampus; cell
culture; immunofluorescence
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INTRODUCTION |
The mechanisms regulating the
differentiation and molecular composition of the postsynaptic apparatus
are best understood for the neuromuscular junction (NMJ). The tyrosine
receptor kinase MuSK plays an essential role in initiating
prepatterning of acetylcholine receptors (AChRs) in muscle cells and
mediates trans-synaptic signaling of agrin, which is
required for proper formation of the NMJ and its association with
proteins forming the dystrophin-associated protein complex (DPC) (for
review, see Sanes and Lichtman, 1999; Davis et al., 2001; Ferns and
Carbonetto, 2001). In the CNS, the postsynaptic density of excitatory
synapses is well characterized, containing a complex of >70 identified
proteins, including glutamate receptors, scaffolding proteins, and
signaling molecules (Husi et al., 2000; Walikonis et al., 2000; for
review, see Craig and Boudin, 2001). An immediate-early gene product,
Narp, has been proposed as a putative candidate for
trans-synaptic signaling-inducing clustering of AMPA
receptors (O'Brien et al., 1999). In contrast, inhibitory synapses are
much less well understood. Gephyrin was identified as a
scaffolding protein essential for clustering of both glycine and
GABAA receptors, and only a few additional
proteins have been identified so far (for review, see Kneussel and
Betz, 2000; Luscher and Fritschy, 2001; Moss and Smart, 2001). They include dystrophin, which is present in a subset of GABAergic synapses
(Knuesel et al., 1999, 2001), raising an interesting analogy to the NMJ.
Apposition of neurotransmitter receptors to the appropriate presynaptic
terminals requires trans-synaptic signaling, as shown in several experimental preparations (Kirsch and Betz, 1998; Levi et
al., 1998, 1999; Rao et al., 2000). Activity-dependent neurotransmitter release is an attractive candidate for this signal. However, except for
glycine receptors (Kirsch and Betz, 1998; Levi et al., 1998), activity
blockade or receptor blockade does not affect receptor clustering
(Craig et al., 1994; Verderio et al., 1994; Mammen et al., 1997;
Cottrell et al., 2000; Rao et al., 2000). Furthermore, there is
evidence that presynaptic signaling from neurochemically distinct types
of interneurons might determine postsynaptic receptor composition in
GABAergic synapses on hippocampal pyramidal cells (Maccaferri et al.,
2000; Nyiri et al., 2001). Thus, one can expect such signals to play a
role in the recruitment of specific scaffolding and signaling molecules
to the postsynaptic apparatus.
Rao et al. (2000) showed mismatched apposition of presynaptic and
postsynaptic components in isolated hippocampal neurons grown on
permissive microislands. Thus, pyramidal cells clustered gephyrin and
GABAA receptors precisely opposite to
glutamatergic autapses. This finding shows that
GABAA receptor and gephyrin clustering are
independent of GABAergic input. It raises important questions,
such as whether all proteins of the postsynaptic apparatus are
independent of appropriate innervation and how presynaptic terminals
recruit appropriate receptors and associated proteins in
multi-innervated neurons.
We used hippocampal primary cultures that contain only a few GABAergic
interneurons to explore immunocytochemically the influence of GABAergic
innervation, visualized with markers for GABAergic presynaptic
terminals, on the distribution of different components of the
postsynaptic apparatus, including the GABAA
receptor 2 subunit, gephyrin, and dystrophin.
We show that gephyrin and dystrophin respond in distinct ways to the
presence or absence of a GABAergic presynapse, suggesting independent
clustering mechanisms for these two proteins.
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MATERIALS AND METHODS |
Animals. Rat embryos [embryonic day (E) 17 or E18]
were obtained from timed mated pregnant OFA [Icolbm: OFA (SPF)] or
Wistar rats (RCC, Füllingsdorf, Switzerland). The
2 subunit-deficient mice were described
previously (Gunther et al., 1995). The animals used here were bred in a
C57BL/6 background. Timed matings between 20/+ mice were
set up, and cultures were prepared for each embryo separately at E15
and correlated with genotypes as described (Essrich et al., 1998). All
experiments were approved by the cantonal veterinary office of Zurich.
Cell culture. Primary cultures of hippocampal neurons were
prepared as described previously (Berninger et al., 1995). Embryos were
taken from pregnant dams anesthetized with ether. The hippocampus was
dissected on ice and incubated for 15 min at 37°C in PBS, pH 7.4, containing 1 mg/ml bovine serum albumin and 12 µg/ml papain (Sigma,
St. Louis, MO). Neurons were subsequently dissociated by gentle
trituration with a fire-polished Pasteur pipette and suspended in DMEM
containing 10% fetal calf serum (Invitrogen, San Diego, CA).
They were then plated on poly-L-lysine
(Sigma)-coated 35 mm Petri dishes (Invitrogen) at a density of 1.5 × 10 4 to 2 × 104
cells/cm2. After 24 hr, the medium was
exchanged with a defined, serum-free medium (Brewer and Cotman, 1989;
Zafra et al., 1990). Feeder layers, prepared from postnatal day (P) 0 rat cortex and plated on coverslips, were placed upside down above the
neurons. Cultures were kept at 37°C in a 5%
CO2 humidified incubator.
Immunocytochemistry on cell cultures. All experiments were
performed on mature cultures (21-28 d in vitro). To ensure
selective detection of GABAA receptors in the
cell membrane, living cells were incubated with
2 subunit-specific antibodies raised against extracellular epitopes (for characterization, see Fritschy and Mohler,
1995). The living cultures were incubated for 90 min at room
temperature with antibodies (affinity-purified, 1.2 µg/ml) diluted in
Ringer's solution (in mM):
CaCl2 2, MgCl2 2, glycine 0.001, TTX 0.0005, glucose 30, HEPES 25, KCl 5, NaCl 119, pH 7.4 (Archibald et al., 1998). They were subsequently washed three times for
10 min with Ringer's solution and fixed with methanol for 10 min at
 20°. Fixed cultures were rinsed extensively with PBS and incubated
for 90 min at room temperature with one of the following primary
antibodies in PBS containing 10% normal goat serum (NGS): gephyrin
[monoclonal antibody (mAb)7a; Alexis Corporation, San Diego, CA;
1:400]; rabbit anti-glutamic acid decarboxylase (GAD65/67) (Affiniti,
Exeter, UK; 1:2000) or GAD65 (mAb, GAD-6; Developmental Studies
Hybridoma Bank, University of Iowa, Iowa City, IA; supernatant 1:10);
rabbit anti-GAD67 (Alpha Diagnostics, San Antonio, TX; 1:1000); rabbit
anti-GABA transporter 1 (GAT-1, DiaSorin, Stillwater, MN; 1:3000);
rabbit anti-vesicular inhibitory acid transporter (VIAAT) (Dumoulin et
al., 1999) (kindly provided by Dr. B. Gasnier, Paris, France; 1:5000);
rabbit anti-vesicular glutamate transporter (vGluT1) (BNP1) (Bellocchio
et al., 2000; Takamori et al., 2000) (Synaptic Systems, Goettingen,
Germany; 1:10,000); rabbit anti-synapsin I (Molecular Probes, Eugene,
OR; 1:300); anti-synaptophysin (mAb, Roche Diagnostics, Rotkreuz, Switzerland; 1:1000); anti-dystrophin, C terminus (mAb, Anawa Trading
SA, Wangen, Switzerland; 1:50); anti--dystroglycan (DG) (mAb,
Novocastra, Newcastle, UK; 1:20); and anti-syntrophin (mAb, pan,
provided by Dr. S. C. Froehner, University of Washington, Seattle,
WA; 1:20). Cultures were subsequently washed three times for 10 min
with PBS and incubated with a mixture of secondary antibodies
conjugated to Cy3 or Cy5 (Jackson ImmunoResearch, West Grove, PA;
1:500) or Alexa 488 (Molecular Probes; 1:1000) for 60 min at room
temperature in PBS plus 10% NGS. After three washes in PBS, cells were
coverslipped in 50% glycerol in 0.2 M sodium bicarbonate buffer, pH 9.2.
Data analysis. All experiments were analyzed by conventional
fluorescence microscopy using a high-resolution digital camera (Hamamatsu Orca, Hamamatsu Photonics, Hamamatsu City, Japan) and the
OpenLab imaging Software (Improvision, Coventry, UK). Semiquantitative analyses were performed on randomly selected samples of 80-120 segments of dendrites (50 or 100 µm) from at least 12 cells in three
independent cultures from E17 and E18 rats (see Fig. 2, Tables 1, 2).
Clusters were counted with the OpenLab counting tool. All measurements
were expressed as mean ± SD. Statistical analysis was performed
using Student's t test. Digital images were processed using
the software Imaris (Bitplane, Zurich, Switzerland).
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RESULTS |
Cultures of hippocampal neurons prepared from E17 or E18 rat
embryos, plated at a density of ~20,000
cells/cm2 and maintained for 21-28 d
in vitro, were characterized by morphologically mature cells
and a high density of synapses, as detected with markers of both
glutamatergic and GABAergic presynaptic and postsynaptic elements.
Staining for GAD65 revealed a low density of GABAergic interneurons
(0.2-5% of total cell number), which form a population of large cells
(mean soma diameter, 60 µm) with smooth dendrites and expressing a
prominent GABAA receptor
1 subunit-immunoreactivity (IR)
(Brünig et al., 2002). However, GAD-positive axons typically formed an extensive plexus of beaded fibers innervating neighboring cells. As a result, only some areas of the culture were covered with
GABAergic axons, whereas adjacent regions were devoid of GABAergic
innervation. Cultures derived from E18 rats contained on average more
interneurons and matured faster than E17 cultures. The neurochemical
identity of GAD-positive axons was verified with antibodies against the
GABA transporters VIAAT and GAT-1, which produced staining patterns
identical to those of GAD and therefore selectively labeled GABAergic
axons. In contrast, no specific staining was obtained with antibodies
against GAD67 (data not shown), suggesting that this isoform is not
expressed in vitro. The inhomogeneous distribution of
GABAergic axons in our cultures provided the opportunity to compare the
distribution of GABAA receptors and associated
postsynaptic proteins, such as gephyrin and dystrophin, in cells
receiving strong GABAergic input and in cells receiving little or no
GABAergic innervation.
Mismatched apposition of GABAA receptors and gephyrin
to glutamatergic terminals
As reported previously (Essrich et al., 1998; Brünig et al.,
2001, 2002), staining for the GABAA receptor
2 subunit revealed a clearly punctate
immunoreactivity distributed on the soma and dendrites of pyramid-like
cells (Fig. 1a). These puncta
were extensively colocalized with gephyrin-IR (Fig. 1a,
insets), representing postsynaptic clusters. Because a
diffuse, presumably extrasynaptic, 2 subunit staining was also seen, clusters were defined by their intensity (more
than twice the intensity of the surrounding membrane) and their
apparent diameter (>0.3 µm; 100× oil immersion lens, numerical aperture 1.4). Postsynaptic receptor clusters can also be revealed by
staining with the 2,3 or
2 subunit, indicating that they represent
functional GABAA receptors (Craig et al., 1994,
1996; Essrich et al., 1998; Brünig et al., 2001). In
cultures with a low density of GABAergic axons, some
2 subunit and gephyrin clusters were closely
apposed to GABAergic terminals, as shown by triple immunostaining
with GAD (Fig. 1a), VIAAT, or GAT-1 (data not shown).
These synapses were characterized by groups of
GABAA receptor and gephyrin clusters surrounding
a GABAergic bouton (Fig. 1b), suggesting that each
presynaptic terminal formed as many release sites. These clusters
represented appropriately matched GABAergic presynaptic and
postsynaptic elements.
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Figure 1.
Formation of appropriately matched and
mismatched synapses in the same neuron. a, Triple
immunofluorescence staining for the 2 subunit
(red), gephyrin (green), and GAD
(blue) (see also insets) showing a
pyramid-like cell contacted by a single GABAergic axon. Particularly
brightly stained 2 and gephyrin clusters are grouped
along the trajectory of a GAD-positive axon. In addition,
2 and gephyrin colocalize in many smaller clusters
evenly distributed over dendrites (arrowheads), which
are not apposed to GABAergic boutons. Diffuse 2 subunit
staining of dendrites is attributable to nonclustered, extrasynaptic
GABAA receptors. Scale bar, 5 µm. b,
Triple staining of the 2 subunit (red),
gephyrin (green), and GAD (blue).
Each GABAergic bouton is surrounded by multiple 2- and
gephyrin-positive clusters, suggesting the presence of as many release
sites facing postsynaptic specializations. The 2 and
gephyrin clusters that are not apposed to GABAergic terminals
(arrows) form single clusters. Scale bars, 2 µm.
c, Triple staining of the 2 subunit
(red), vGlut1 (green), and GAD
(blue) of a cell contacted by a single GABAergic axon.
The 2 subunit clusters, which are not apposed to
GAD-positive boutons, are apposed to a Glut1-positive, glutamatergic
terminals (inset) and represent mismatched synapses.
Scale bar, 5 µm. d, Double staining of gephyrin
(red) and vGlut1 (green), depicted
at high magnification. Again, most gephyrin clusters are apposed to
vGlut1-positive boutons. Scale bar, 1 µm.
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The remaining 2 subunit and gephyrin clusters
not apposed to GABAergic boutons (Fig. 1a,b,
arrowheads) corresponded to mismatched synapses apposed to
glutamatergic terminals (90.4 ± 10.6%) (Table 1), as shown by triple staining for
2, GAD, and the glutamate transporter vGlut1
(Fig. 1c). Gephyrin clusters also were frequently apposed to
vGlut1-positive terminals, as expected from their colocalization with
the 2 subunit (Fig. 1d). Therefore,
mistargeting of gephyrin and GABAA receptors to
glutamatergic terminals occurs in hippocampal neurons that receive
limited GABAergic input. We have shown previously that gephyrin
does not colocalize with postsynaptic density protein 95 (PSD95) or the
glutamate receptor GluR1 subunit at postsynaptic sites
(Brünig et al., 2002). Thus, mismatch of GABAergic postsynaptic elements to glutamatergic terminals apparently leads to the formation of nonfunctional synapses.
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Table 1.
GABAA receptors cluster in both GABAergic and
mismatched synapses, whereas the DPC is found exclusively in
appropriately matched GABAergic synapses
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To determine whether the density of GABAergic input influences the
formation of mismatched synapses, the distribution of
2 subunit clusters was compared in cells
contacted by low, intermediate, or high numbers of GAD-positive
terminals (Fig. 2). In a given culture
dish, pyramidal cells receiving no GABAergic input had numerous
clusters of 2 subunit-IR evenly distributed
over dendrites, presumably targeted to glutamatergic terminals (Fig.
2a-c). Cells contacted by only one or a few GABAergic axons
formed characteristic groups of 2 subunit
clusters along trajectories of GAD-positive fibers (Figs.
1a, 2d-f), representing GABAergic
synapses. In the remaining dendrites of these cells, numerous
2 subunit clusters were evident, corresponding
to mismatched synapses. Finally, in cells contacted by many GABAergic
axons, typically surrounding the soma and proximal dendrites, nearly
all 2 subunit clusters were apposed to
GAD-positive varicosities (Fig. 2g-i). In such cells, there
was no evidence of mismatched synapses (Fig. 2i). This was
confirmed by triple staining with gephyrin (data not shown), which in
these cells was found exclusively in 2 subunit clusters apposed to GAD-positive terminals. A semiquantitative analysis
of this effect revealed a negative correlation between the number of
mismatched and GABAergic synapses on dendrites (Fig. 2j)
(correlation coefficient 0.71; p < 0.001). These
results suggest that GABAergic terminals provide an anterograde signal leading to preferential recruitment of GABAA
receptors and gephyrin.
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Figure 2.
The formation of mismatched synapses
depends on the density of GABAergic input, as illustrated for three
representative cells found in the same culture dish. a,
d, g, 2 subunit staining
(red); b, e,
h, GAD staining (green);
c, f, i, overlay for the
boxed areas. a-c, Pyramid-like cell displaying numerous
2 subunit-positive clusters (a)
evenly distributed over its dendrites, although it receives no
detectable GABAergic input (b). These clusters
obviously represent mismatched synapses. d-f, Example
of a cell with brightly stained "chain-like" 2
clusters (d, arrows) along the GABAergic
fiber running over its dendrites (e) representing
appropriately matched GABAergic synapses. In addition, this cell
displays numerous evenly distributed 2 subunit clusters
on its dendrites, corresponding to mismatched synapses.
h, i, Pyramid-like cell innervated by
numerous GAD-positive axons (h). Clusters of
2 subunit staining (i) are seen
only on dendrites contacted by the GABAergic fiber. The overlay
(i) shows that every 2 subunit
cluster is apposed to a GAD-positive bouton. The remaining staining
represents nonclustered, extrasynaptic 2
GABAA receptors. j, Number of mismatched
synapses as a function of the density of GABAergic synapses on
dendrites. Synapses were counted on 50 µm segments of dendrites
(n = 64) from 20 cells with variable GABAergic
innervation. GABAergic synapses were identified by 2
subunit clusters closely apposed to GAD-positive boutons. Isolated
2 subunit clusters were counted as mismatched
synapses. Each dot represents one segment. An
inverse correlation is evident. Black line, Linear
regression. Correlation coefficient, 0.71, p < 0.001. Scale bars: a, b,
d, e, g, h,
10 µm; c, f, i, 5 µm.
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Dystrophin and the dystrophin-associated protein complex cluster
exclusively opposite GABAergic terminals
In rodent hippocampus, cortex, and cerebellum, dystrophin is
colocalized with GABAA receptor subunits and
gephyrin in presumptive GABAergic synapses (Knuesel et al., 1999). We
show here that dystrophin is detectable also in vitro,
forming strongly labeled puncta distributed on the soma and dendrites
of cultured hippocampal neurons (Figs. 3a, 4b). The
antibody used is directed against the C terminus of the protein and
recognizes both full-length and N-terminally truncated isoforms of
dystrophin. Double immunofluorescence staining with GAD confirmed that
dystrophin clusters were associated with GABAergic synapses, because
they were always apposed to GAD-positive boutons (Fig.
3a-c). In many cases, several dystrophin clusters surrounded a GAD-positive bouton, as described for the
2 subunit and gephyrin in GABAergic synapses
(Fig. 3c, arrows). The fraction of GAD-positive
boutons surrounded by dystrophin clusters was on average 89.9 ± 6%, as measured on dendrites (Table 1). As was the case in
vivo, dystrophin-IR was restricted to GABAergic postsynaptic sites
(96.3 ± 1.7% of the dystrophin clusters were associated with
GAD) (Table 1).
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Figure 3.
Dystrophin clusters opposite GABAergic terminals.
Double immunofluorescence staining of dystrophin (a,
red) and GAD (b, green),
with overlay (c). Staining of dystrophin
(antibody recognizing the C terminus) revealed strongly stained puncta
aligned in chains (a). Sometimes groups of
clusters were apparent (c, arrows).
Costaining with GAD demonstrates that virtually all dystrophin clusters
were apposed to GAD-positive terminals. Scale bars, 10 µm.
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Double- and triple-labeling studies with dystrophin, the
2 subunit, and GAD revealed that dystrophin
clusters were colocalized with GABAA receptors in
GABAergic synapses. In cells innervated by a few GAD-positive axons,
forming both matched and mismatched synapses, dystrophin-IR was
detected only in the groups of clusters typically surrounding
GAD-positive boutons (Fig.
4a-c). The colocalization of
2 and dystrophin was confirmed in
high-magnification images showing that dystrophin clusters were
directly apposed to a GAD-positive bouton and were colocalized with the
2 subunit (Fig. 4d-g). Mismatched 2 subunit clusters in the same neuron lacked
detectable dystrophin-IR (Fig. 4, arrowheads). In dendrites,
only a few appropriately matched GABAergic synapses lacked
dystrophin, which was evidenced by the fact that 87.2 ± 10.5% of
2 clusters apposed to GAD were colocalized with dystrophin (Fig. 4, Table 1). Altogether, these results indicate
that, in contrast to gephyrin, dystrophin was never mistargeted to
glutamatergic terminals. Thus, clustering of dystrophin and of gephyrin
is regulated by distinct mechanisms.
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Figure 4.
Dystrophin is colocalized with the
2 subunit in GABAergic synapses and is not mistargeted
to glutamatergic terminals. a-c, Double staining of the
2 subunit (a, red) and
dystrophin (b, green), with overlay
(c). Dystrophin-positive clusters are colocalized
with brightly stained 2 subunit clusters
(c, yellow). They appear in chain-like
groups, indicating the presence of a GABAergic axon. Many additional
2 subunit clusters, presumably corresponding to
mismatched synapses, are not labeled with dystrophin.
d-g, Representative examples of triple staining of the
2 subunit (red), dystrophin
(green), and GAD (blue).
d, f, g, 2
and GAD; e, f', g',
dystrophin and GAD in the same fields. Dystrophin clusters are found
only at sites apposed to GABAergic terminals, where they are
colocalized with the 2 subunit (d,
e, thin arrows). d-g,
Arrowheads point to mismatched synapses labeled with the
2 subunit but not with dystrophin. The 2
and dystrophin did not colocalize without apposition to a GABAergic
terminal. However, occasional 2 subunit clusters in a
GABAergic synapse were not matched by dystrophin
(f). Scale bars: a-c, 10 µm;
d, e, 5 µm.
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At the NMJ, dystrophin is associated with a multimeric
transmembrane protein complex, the DPC. We have therefore
investigated whether other members of the DPC, such
as -dystroglycan and syntrophin, are also located at
GABAergic synapses in vitro. Immunofluorescence staining
with monoclonal antibodies recognizing -DG or all three isoforms of
syntrophin (1-, 1-,
and 2-syntrophin), respectively, revealed, for
both markers, brightly labeled puncta arranged in lines running over
cell bodies and dendrites (Fig.
5a-l) and apposed to
GAD-positive terminals (Fig. 5a-i). Sometimes, as seen for dystrophin, groups of clusters surrounded one bouton (Fig.
5d-f) exhibiting the typical morphology for
appropriately matched GABAergic synapses. Both -DG (Fig.
5j-l) and syntrophin (data not shown) were
colocalized extensively with the 2 subunit.
Mismatched synapses did not contain -DG (Fig. 5l,
arrowheads) or syntrophin. The fraction of GABAergic
synapses positive for either of these DPC proteins was smaller than for
dystrophin, however (73.1 ± 8% of GAD boutons apposed to
syntrophin and 74 ± 2% of GAD boutons apposed to -DG) (Table
1). This implies either that only a subpopulation of GABAergic synapses
contains dystrophin together with additional DPC proteins or that the
antibodies specific for -DG or syntrophin are less sensitive than
those for dystrophin. Conversely, clusters of -DG-IR or
syntrophin-IR were always associated with GABAergic terminals
(95.3 ± 4% for -DG and 94.1 ± 5% for syntrophin) (Fig. 5, Table 1) and not mistargeted to glutamatergic synapses. Therefore, we show that three proteins of the DPC, dystrophin, -DG, and syntrophin, are part of the postsynaptic specialization of GABAergic synapses in cultured hippocampal neurons. The fact that DPC proteins are never mistargeted to glutamatergic presynaptic terminals suggests a
common clustering mechanism that involves signaling with GABAergic presynaptic terminals.
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Figure 5.
Syntrophin- and -dystroglycan
cluster opposite GABAergic terminals and colocalize with
2 GABAA receptors. a-f,
Double immunofluorescence staining of pan-syntrophin
(a, d, red) and GAD
(b, e, green), with
overlay (c, f).
a-c, Low magnification; d-f, high
magnification. Staining of syntrophin revealed bright clusters
(a, arrows) aligned in chains coinciding
with GABAergic terminals stained with GAD (b,
arrows). d, e, Typical
grouping of postsynaptic specializations around GABAergic
boutons. g-i, Double immunofluorescence staining of
-dystroglycan (d, red) and GAD
(e, green); overlay in i.
Strongly stained -dystroglycan clusters are apposed to GAD-positive
boutons. j-l, Double immunofluorescence
staining of 2 (j,
red) and -dystroglycan (k,
green); overlay in l. The two markers
colocalize in chain-like structures representing appropriately matched
GABAergic synapses, but not in mismatched synapses
(arrowheads). Scale bars: a-c,
g-i, 10 µm; d-f, 2 µm;
j-l, 5 µm.
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Clustering of DPC proteins is independent of postsynaptic
GABAA receptors and gephyrin
The GABAA receptor
2 subunit is essential for postsynaptic
clustering of GABAA receptors and gephyrin, as
shown in vitro and in vivo in neurons from
20/0 mice
(Essrich et al., 1998), indicating that gephyrin and
GABAA receptors are interdependent components of
the GABAergic postsynaptic apparatus. We used hippocampal primary
cultures of E15
20/0 mouse
embryos to investigate whether clustering of the DPC is dependent on
the presence of postsynaptic gephyrin and GABAA receptors.
As expected, clustering of the 2 subunit was
intact in 2+/+
neurons (Fig. 6a) but greatly
reduced in neurons from
20/0 mice (Fig.
6b). Likewise, gephyrin-positive clusters were dramatically reduced in cultures from mutant mice (data not shown). Remarkably, however, the punctate staining of dystrophin (Fig.
6c,d) and -DG (Fig.
6e,f) was unaffected by the absence of
postsynaptic GABAA receptors and gephyrin. The
size and density of clusters covering dendrites and somata of neurons
were similar in cultures of wild-type and
20/0 mice, as
revealed by statistical analysis (Fig. 6c-f,
Table 2). This result confirms
that gephyrin and the DPC are independent postsynaptic components of
GABAergic inhibitory synapses and clustered by distinct mechanisms.
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Figure 6.
Clustering of DPC-proteins is unaffected in
20/0 mutant mice. a,
b, Loss of 2 subunit-positive clusters in
pyramid-like cells from a 20/0
culture (b) compared with a wild-type,
2+/+ culture
(a). This confirms the requirement of the
2 subunit for postsynaptic clustering of
2-GABAA receptors. c,
d, Dystrophin staining in wild-type
(c) and mutant (d) neurons.
The staining pattern of dystrophin was unaffected by the mutation: in
both genotypes, dystrophin displayed strongly stained clusters on the
soma and dendrites of cultured neurons. e,
f, -Dystroglycan staining of wild-type
(e) and mutant (f)
cultures. Like dystrophin, -dystroglycan staining revealed bright
staining of synaptic clusters independently of the genotype. See Table
1 for semiquantitative results. Scale bars, 10 µm.
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DISCUSSION |
In this study, we show that mismatched apposition of GABAergic
postsynaptic components to glutamatergic presynaptic terminals can
occur in multi-innervated hippocampal cultures. The proportion of
mismatched synapses is inversely proportional to the extent of
GABAergic input. Furthermore, we show that dystrophin is clustered in
association with -dystroglycan and syntrophin at GABAergic postsynaptic sites. The molecular organization of these GABAergic synapses therefore appears homologous to the NMJ. Unlike gephyrin and
GABAA receptors, these DPC proteins were never
mistargeted to the membrane opposite glutamatergic terminals,
suggesting distinct clustering mechanisms for gephyrin and the DPC.
Supporting this idea, DPC clustering is unaffected in
20/0 mice,
although postsynaptic accumulation of GABAA
receptor and gephyrin is strongly impaired. These results suggest that
clustering of the DPC at GABAergic synapses selectively depends on
signaling from presynaptic terminals.
Mismatched apposition of GABAA receptors and gephyrin
to glutamatergic terminals
The occurrence of mismatched synapses in isolated hippocampal
neurons (Rao et al., 2000) was taken as evidence for the existence of
both a "general" factor, leading to unspecific clustering of receptors and associated proteins at postsynaptic sites, and
"transmitter-specific" factors responsible for appropriate matching
of presynaptic and postsynaptic elements in multi-innervated cells.
Here, we show that mismatched apposition of GABAA
receptor and gephyrin clusters to glutamatergic terminals occurs even
in neurons receiving sparse GABAergic innervation, suggesting that the
general synaptogenic factor(s) also operates when neurons receive input
from more than one neurotransmitter. Nevertheless, the absence of
mismatched synapses in cells innervated by multiple GABAergic axons
(Fig. 2g-j) indicates that the specific signal(s) is
dominant over the general clustering signal.
Because GABAA receptors and gephyrin do not seem
to interact directly, it is assumed that they are linked by additional
protein(s). Mistargeting of gephyrin and GABAA
receptor clusters to sites of glutamatergic input shows, however, that
these putative linker proteins cannot be specific for GABAergic
synapses. They either are found in all postsynaptic sites or, more
likely, are preassociated with either gephyrin or
GABAA receptors before coclustering at postsynaptic sites. The mismatched synapses rule out a requirement of
local GABAA receptor activation for clustering,
as has been postulated for glycine receptors (Kirsch and Betz, 1998;
Levi et al., 1998). Therefore, clustering of glycine and
GABAA receptors, although requiring gephyrin in
both cases, probably is governed by distinct mechanisms.
Mismatched synapses are most likely nonfunctional, as shown by mutual
exclusion of glutamatergic and GABAergic postsynaptic proteins (Rao et
al., 2000; Brünig et al., 2002), raising the question of their
physiological significance. In vivo, mistargeting of
GABAA receptors to glutamatergic terminals is
unlikely to occur in the hippocampus, because on CA1 pyramidal cells,
GABAergic innervation is established before glutamatergic innervation
(Tyzio et al., 1999). However, Nusser et al. (1996) reported the
presence of the GABAA receptor
6 subunit postsynaptic to mossy fiber inputs in cerebellar glomeruli, suggesting that misplaced
GABAA receptors are not just an in
vitro artifact.
Differential mechanisms of gephyrin and dystrophin clustering
Our results demonstrate two principal differences in clustering of
gephyrin and dystrophin at postsynaptic sites: (1) gephyrin, but not
dystrophin, requires the GABAA receptor
2 subunit for clustering at GABAergic
synapses; (2) dystrophin, but not gephyrin, clusters selectively
opposite GABAergic terminals. The two proteins therefore appear to
serve independent functions. In agreement, clustering of gephyrin was
unaffected by the lack of dystrophin in mdx mice (Knuesel et
al., 1999), although the number and size of GABAA
receptor clusters was significantly reduced in these mutants.
In vivo, residual 2,
3, 2/3, and
2 GABAA receptor
clusters have been observed in spinal cord and organotypic retina
cultures of neonatal gephyrin0/0 mice
(Fischer et al., 2000; Kneussel et al., 2001). The significance of this
observation is unclear, but it suggests the existence of
gephyrin-independent clustering mechanisms. Dystrophin is unlikely to
mediate this type of gephyrin-independent clustering, because it is
detected at late postnatal stages only (Knuesel et al., 2000).
Putative role of dystrophin and the DPC in central synapses
The demonstration that dystrophin is closely associated with
-DG and syntrophin suggests that the entire DPC, including
dystrobrevin and -DG (Ervasti and Campbell, 1991; Grady et al.,
2000), is enriched in a subset of central inhibitory synapses. Given
the high degree of homology between GABAA and
AChR subunits (Ortells and Lunt, 1995), it is not surprising to find
that corresponding synapses share at least some of their protein
components. At the NMJ, the DPC is essential for maturation of the
postsynaptic apparatus and for long-term maintenance of AChR clusters,
but not for initial receptor clustering (Grady et al., 2000). A similar
role of the DPC at GABAergic synapses is consistent with the fact that
dystrophin is first detectable only at P14 in rats (Knuesel et al.,
1999). Thus, initiation of GABAA receptor
clustering is clearly independent of dystrophin.
Interestingly, glutamatergic synapses on mature neurons are
unsusceptible to actin depolymerization, but in young neurons, the
synaptic apparatus depends on F-actin (Zhang and Benson, 2001). The
actin independence correlates with the acquisition of scaffolding molecules, such as Bassoon, on the presynaptic site and PSD95 in
excitatory postsynapses (Zhang and Benson, 2001). Allison et al. (2000)
have shown that GABAA receptor and gephyrin
clusters in hippocampal neurons also are unaffected by depolymerization of microtubules or actin or by detergent extraction, suggesting a
stabilizing scaffold at inhibitory synapses. The DPC might play this
role in GABAergic postsynapses, which would explain the altered clustering of GABAA receptors in adult
mdx mice (Knuesel et al., 1999).
Given the fact that dystrophin is expressed in regions of the brain
that display the highest levels of plasticity (cerebral cortex,
hippocampus, cerebellum), two general possibilities for the function of
the DPC are conceivable. First, because dystrophin expression is
increased late in development (Knuesel et al., 1999), it might be
paralleled by a decrease in synaptic plasticity in rodent brain. By
stabilizing the postsynaptic apparatus, the DPC might "freeze"
GABAergic synapses to maintain a certain status of the network once
learning processes have been primarily completed in rats.
Alternatively, the DPC might provide a scaffold, enabling changes in
clustered GABAA receptor number without losing
the postsynaptic apparatus, as might be required in circuits with a
high degree of synaptic plasticity. Assuming that the DPC is stably
associated with the presynapse, the existence of "empty" synapses,
transiently devoid of GABAA receptors, would be possible.
The selective presence of dystrophin and associated proteins in
GABAergic synapses in our cultures suggests that their aggregation is
triggered by a signal specific for GABAergic terminals. Although agrin
is well known to induce neurotransmitter receptor clustering at the
NMJ, homologous synapse-specific signals have not yet been identified
in the CNS. Whether soluble factors or, alternatively, transmembrane
cell adhesion molecules operate at GABAergic synapses to recruit the
DPC remains to be elucidated.
| |
FOOTNOTES |
Received Sept. 27, 2001; revised Jan. 22, 2002; accepted March 8, 2002.
This project was supported by the Swiss National Science Foundation
(Grant 31-52869.97). We thank Dr. H. Möhler for his continuous support and insight and Corinne Sidler for technical assistance. We are
grateful to Dr. B. Gasnier (Centre National de la Recherche Scientifique, Institut de Biologie Physico-Chimique, Paris,
France) and to Dr. S. C. Froehner (University of Washington,
Seattle, WA) for a generous supply of antibodies against VIAAT and
syntrophin, respectively.
Correspondence should be addressed to Dr. Jean-Marc Fritschy, Institute
of Pharmacology and Toxicology, University of Zurich, Winterthurerstraße 190, CH-8057 Zurich, Switzerland. E-mail:
fritschy{at}pharma.unizh.ch.
I. Knuesel's present address: California Institute of Technology, Mail
Code 216-76, Pasadena, CA 91125.
| |
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TOP
ABSTRACT
INTRODUCTION
