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The Journal of Neuroscience, July 15, 2001, 21(14):5036-5044
Dynamics of Glycine Receptor Insertion in the Neuronal Plasma
Membrane
Madelaine
Rosenberg,
Jochen
Meier,
Antoine
Triller, and
Christian
Vannier
Laboratoire de Biologie Cellulaire de la Synapse Normale et
Pathologique, Institut National de la Santé et de la Recherche
Médicale U497, Ecole Normale Supérieure, 75005 Paris,
France
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ABSTRACT |
The exocytosis site of newly synthesized glycine receptor was
defined by means of a morphological assay to characterize its export
from the trans-Golgi Network to the plasma membrane.
This was achieved by expressing in transfected neurons an  1 subunit bearing an N-terminal tag selectively cleavable from outside the cell
by thrombin. This was combined with a transient temperature-induced block of exocytic transport that creates a synchronized exocytic wave.
Immunofluorescence microscopy analysis of the cell surface appearance
of newly synthesized receptor revealed that exocytosis mainly occurred
at nonsynaptic sites in the cell body and the initial portion of
dendrites. At the time of cell surface insertion, the receptors existed
as discrete clusters. Quantitative analysis showed that glycine
receptor clusters are stable in size and subsequently appeared in more
distal dendritic regions. This localization resulted from diffusion in
the plasma membrane and not from exocytosis of transport vesicles
directed to dendrites. Kinetic analysis established a direct
substrate-product relationship between pools of somatic and dendritic
receptors. This indicated that clusters represent intermediates between
newly synthesized and synaptic receptors. These results support a
diffusion-retention model for the formation of receptor-enriched
postsynaptic domains and not that of a vectorial intracellular
targeting to synapses.
Key words:
glycine receptor; synapse; spinal cord neuron; exocytosis; diffusion/retention; transfection
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INTRODUCTION |
Signal transmission between neurons
relies on a precise distribution of ion channels and neurotransmitter
receptors within distinct plasma membrane domains over axonal and
dendritic compartments. In this respect, synapses represent highly
organized structures in which complex assemblies of transmembrane and
cytoplasmic proteins enable communication between presynaptic and
postsynaptic cells. As highlighted for central excitatory synapses,
numerous interactions within these complexes regulate receptor
localization by mediating their clustering and/or anchoring to
cytoskeleton (Fanning and Anderson, 1999 ; Kim and Huganir, 1999;
Garner et al., 2000).
In inhibitory synapses, similar mechanisms operate to localize glycine
receptors (GlyRs) and GABAA receptors
(GABAARs). GlyR was the first CNS
neurotransmitter receptor shown to accumulate in postsynaptic membrane
areas coextending with patches of the cytoplasmic tubulin-binding
protein gephyrin (Triller et al., 1985, 1987; Kirsch et al., 1991;
Vannier and Triller, 1997; Colin et al., 1998). Gephyrin, which also
binds the GlyR  subunit (Meyer et al., 1995), is required for
tethering GlyR as clusters within postsynaptic loci (Kirsch et al.,
1993; Feng et al., 1998). Although direct binding to
GABAAR has not been demonstrated, gephyrin also mediates synaptic clustering of GABAAR 2 and
 2 subunits (Essrich et al., 1998; Kneussel et al., 1999;
Lévi et al., 1999).
It is not known how postsynaptic proteins, and among them
neurotransmitter receptors, are delivered to their appropriate domain in the plasma membrane. So far, investigations on the formation of
compartments in neurons have mainly been focused on sorting events in
the acquisition of cell polarity (Winckler and Mellman, 1999). They
suggested that direct vesicular pathways exist for segregation of
several proteins in the dendritic plasma membrane (de Hoop et
al., 1995; Jareb and Banker, 1998; Stowell and Craig, 1999). In
contrast, axonal targeting, which also uses vesicular pathways, may
rely on an additional selective sorting event, operating downstream of
transport (Burack et al., 2000). The mosaic-like organization of the
neuronal surface adds another complexity level and raises questions as
to how selective postsynaptic receptor accumulation is achieved in
dendrites. In particular, it remains to be explored whether receptor
exocytosis is directed and synapse-specific or occurs randomly before
receptor-specific retention in synapses (Craig et al., 1994).
In previous work using neurons expressing various GlyR subunits, we
showed that formation of receptor clusters precedes their gephyrin-mediated stabilization in synaptic loci (Meier et al., 2000).
Here, we determined the transport route of newly synthesized GlyR in
transfected neurons. We used a GlyR 1 subunit bearing an N-terminal
tag selectively cleavable from outside the cell by thrombin. This
allowed the selective detection of intracellular or cell surface
receptor. A nearly synchronized transport of GlyR to the cell surface
was obtained with a temperature-induced block of trans Golgi
Network (TGN) exit. With these tools, we show that: (1) GlyR clusters
are formed after plasma membrane insertion, (2) GlyR exocytosis is not
directed and synapse-specific, and (3) GlyR exocytosis occurs
predominantly at extrasynaptic sites in the soma and initial portions
of dendrites, and clusters subsequently diffuse to the distal dendritic
plasma membrane before postsynaptic retention.
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MATERIALS AND METHODS |
DNA constructs. The GlyR 1 subunit cDNA was
modified as described (Meier et al., 2000) by inserting between the
second and third amino acids of the mature protein the sequences
encoding either the EQKLI SEEDL peptide from c-myc or the YPYDVPDYA
peptide from hemagglutinin (HA), yielding myc:: 1 and
HA:: 1, respectively. The thrombin cleavage sequence LVPRGS
was introduced immediately after the c-myc sequence in
myc:: 1 by site-directed mutagenesis (GeneEditor system;
Promega, Charbonnières, France) using the oligonucleotide
5' TCT GAG GAG GAT CTA-GTA-CCC-CGA-GGA TCT GCA CCC AAG CCT 3'. This
resulted in the final EQKLISEEDLVPRGS sequence, yielding
myc-Thr:: 1. cDNA constructs were subcloned in the
eukaryotic expression vector derived from pEGFP-N1 (after removal of
EGFP coding sequence; Clontech, Palo Alto, CA) allowing a
cytomegalovirus promoter-driven expression. This yielded
plasmids pC-myc:: 1, pC-HA:: 1, and
pC-myc-Thr:: 1, respectively. All cDNAs were verified by
dideoxy sequencing, and all plasmids were prepared by anion-exchange
chromatography (resin from Qiagen S.A., France).
Cell culture and transient transfections. Spinal cord
neurons from Sprague Dawley rats were prepared at day 14 of gestation, or embryonic day 14 (E14), as previously described (Meier et
al., 2000). Routinely, they were plated at a density of 7.5 × 10 4
cells/cm2 onto glass coverslips (12 mm
diameter) coated with 15 µg/ml
poly-DL-ornithine (Sigma, St. Louis, MO) in 16 mm
wells. After the neurons had attached, coverslips were transferred
(cell-side down) to dishes containing a confluent layer of glial cells.
They were then cultured for up to 9 d, in a 5%
CO2 atmosphere at 37°C. Glial cell suspensions obtained at E14 were plated at a density of 4 × 104
cells/cm2 in 35 mm dishes coated with 15 µg/ml poly-DL-ornithine and grown for 2 weeks
to confluence in complete L15 culture medium) supplemented with
10% horse serum (Life Technologies, Gaithersburg, MD), at 37°C and
5% CO2. Culture medium was changed after 7 d. The day before neuron plating, glial cells were transferred to
serum-free Neurobasal medium supplemented with B27 (Life Technologies)
(Brewer et al., 1993). Transfection of neurons was performed 6-8 d
after plating by polyethylenimine (PEI) adenofection as previously
described (Meier et al., 2000.) Briefly, neurons on coverslips were
transferred to 16 mm wells containing 300 µl of fresh serum-free
Neurobasal medium, supplemented with 0.25 mM
L-glutamine (Life Technologies) equilibrated at
37°C and 7.5% CO2. For one well, 300 ng of DNA was complexed in 0.15 M NaCl with PEI (800 kDa;
Fluka, Neu-Ulm, Germany; molar charge ratio
r+/- = 3) and 2.25 × 107 pfu of
adenovirus (replication-deficient, Ad-RSV-nlsLacZ). After a 2 hr
incubation with the complex, the neurons were returned to the glial
cell monolayer for exogene expression for up to 24 hr. In
cotransfection experiments, a plasmid molar ratio
pC-myc-Thr:: 1/pC-HA:: 1, or
pC-myc-Thr:: 1/pEGFP-N1 of 1 was used.
African green monkey kidney (COS-7) cells were plated on glass
coverslips and grown in DMEM (Life Technologies) containing 10%
fetal calf serum (FCS; Life Technologies) at 37°C and 7.5% CO2. For transfection, experiments were performed
on subconfluent cultures (60% confluency) using the DEAE-Dextran
method. Usually, 2 µg of plasmid DNA was added to 35 mm dishes.
Transient protein expression was allowed to proceed for 24 hr at 37°C
and 7.5% CO2.
Thrombin treatment of transfected cells. Cleavage of the
c-myc tag from the cell surface myc-Thr:: 1 GlyR subunit
was performed as follows: after 14-16 hr of exogene expression,
transfected cells were washed twice with air-equilibrated minimal
essential medium (MEM; Life Technologies) supplemented with 10 mM HEPES, 4 mM
NaHCO3, 20 mM glucose, 2 mM glutamine, 0.11 mg/ml pyruvate, and 1 mg/ml
chicken egg albumin (Sigma). The cells were then incubated at 19.5°C
for 1 hr in the same medium containing 2.5 U/ml of thrombin (Roche
Diagnostics). Cells were then washed in the same medium without
thrombin and returned to their initial culture medium at 37°C
(restoration phase) (Fig. 1) for the
indicated time period. When required, cells were subjected after a
restoration phase to a second thrombin treatment at 4°C before
fixation. In this case, only intracellular tags remained on the GlyR
subunit. These various incubation periods affected neither cell
viability nor expression of endogenous GlyR or gephyrin and did not
alter the TGN-38 perinuclear localization (data not shown).
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Figure 1.
Structure of GlyR constructs and strategy for cell
surface tag cleavage. A, Diagram of the structures of
the tagged forms of 1 subunit. The gray and
black boxes are the HA and c-myc sequences,
respectively, introduced after the indicated N-terminal amino acid
residues. Hatched boxes represent the four transmembrane
domains, M1-M4. In the myc-Thr:: 1 construct, the thrombin
cleavage sequence is shown between the myc and polypeptide sequences.
B, Temporal sequence of the temperature-induced block of
TGN exit, thrombin digestion of extracytoplasmic receptor, and surface
recovery. The rod is the temporal axis and represents the treatments,
with the indication of their temperature and duration. The thick
arrows indicate the time of thrombin addition and withdrawal,
to and from the culture medium. Small arrows in the
restoration phase indicate time points at which cells are fixed and
processed for immunofluorescence staining. When required, a second
thrombin digestion could be performed at these times before fixation.
C1-D4, Validation of the strategy for cell surface myc
tag cleavage in COS-7 cells. Cells were cotransfected with
pC-myc-Thr:: 1 and pEGFP-N1 and processed according to the
protocol depicted in Figure 1B. The c-myc epitope
was revealed by immunostaining (see Materials and Methods) on living
nonpermeabilized cells before fixation (C) or on
cells subjected to a second thrombin treatment before fixation and
permeabilization (D). Cells were analyzed at  60
min (control cells, C1, D1), or
at 0 (C2, D2), 15 (C3,
D3), and 60 min (C4,
D4) of the restoration phase. The
inset in C2 shows the GFP fluorescence
used to identify the transfected cell. Scale bar, 10 µm.
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Immunofluorescence labeling. Immunofluorescence labeling was
performed essentially as described (Meier et al., 2000).
Extracytoplasmic epitope tags were detected before fixation by
incubating living cells for 30 min at 4°C with primary antibodies
diluted in air-equilibrated MEM medium supplemented with 20 mM glucose and 1 mg/ml BSA. After three washes in
the same medium, cells were fixed and processed as described below.
Intracellular epitope tags were detected during the restoration phase
in cells first treated with thrombin and then fixed and permeabilized,
before incubation with the primary antibodies.
COS-7 cells were fixed in 4% (w/v) paraformaldehyde in PBS for
15 min. Neurons were first fixed in 2% paraformaldehyde and 4%
sucrose in PBS for 5 min and then in 4% paraformaldehyde and 4%
sucrose in PBS for 15 min. Cells were rinsed with PBS, quenched with 50 mM NH4Cl in PBS, and then when
required, permeabilized with PBS containing 0.12% (w/v) Triton X-100
and 0.12% (w/v) gelatin for 4 min. To prevent nonspecific labeling,
cells were blocked with 0.25% (w/v) in PBS for 1 hr. They were then
incubated (1 hr at room temperature) with primary antibodies in
PBS containing 0.12% (w/v) gelatin. After five washes (5 min each)
with the same buffer, the appropriate secondary antibodies were reacted
for 45 min. After four washes, cells were mounted in Vectashield
(Vector Laboratories, Burlingame, CA). Observations were made using the 63×/1.32 objective of a Leica (Nussloch, Germany) DMR
fluorescence microscope. Green fluorescent protein (GFP) was
detected using an FITC filter set.
The primary antibodies were used at the following concentrations: mouse
anti-gephyrin monoclonal antibody (mAb7a), 0.4 µg/ml (Pfeiffer et
al., 1984; Roche Diagnostics); mouse anti-c-myc monoclonal antibody, 1 µg/ml (clone 9E10; Roche Diagnostics); rabbit anti-c-myc polyclonal
antibody, 2 µg/ml (Upstate Biotechnology, Lake Placid, NY); rat
anti-HA monoclonal antibody, 1 µg/ml (clone 3F10; Roche Diagnostics);
and rabbit anti-vesicular inhibitory amino acid transporter antiserum,
1:200 dilution (anti-VIAAT; Dumoulin et al., 1999). Secondary
antibodies were from Jackson ImmunoResearch, West Grove, PA and
used at a dilution of 1:200 [fluorescein (FITC)-conjugated affinity-purified goat anti-rabbit IgG and FITC-conjugated
affinity-purified goat anti-rat IgG (depleted in anti-mouse IgG
activity)], or of 1:500 [carboxymethylindocyanine-3 (Cy3)-conjugated
affinity-purified goat anti-mouse IgG (depleted in anti-rat IgG
activity)].
Quantitative analysis. For all experiments, nonspecific
labeling and the absence of antibody cross-reaction in double-labeling experiments were verified. Fluorescent images were acquired using standard epifluorescence microscopy with a Leica DMR/HCS
microscope (63× or 100× oil immersion objectives) equipped with Cy3
and FITC specific filters and a Hamamatsu CCD camera (C5985). GlyR
clusters were quantified on digitalized images. Neurons (8 < n < 30) from two independent cultures were analyzed.
The total number of GlyR clusters in neuronal compartments was
determined by counting nonoverlapping GlyR clusters in a series of
images taken at different focal planes of the same cell. The number of
GlyR clusters on dendrites was determined by counting the number of
clusters per 5 µm length of dendrite. Mean values ± SEM were
calculated using StatView F4.11 software.
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RESULTS |
Strategy for selective visualization of proteins newly inserted in
the plasma membrane
In previous work we showed that myc-tagged GlyR 1 or 2
subunits expressed in transfected neurons are progressively
incorporated into postsynaptic domains where they colocalize with
gephyrin (Meier et al., 2000). These findings indicated that correct
sorting of exogenous receptor could be reconstituted after neuron
transfection. They also provided the experimental basis for
investigation of the secretory traffic of GlyR and for determination of
its insertion site in the plasma membrane of differentiating neurons.
Recent data from our laboratory show that GlyR 1 and 2 subunit
mRNAs are present beneath postsynaptic loci (Racca et al., 1997;
Gardiol et al., 1999). This localization coupled to an eventual
translation would provide a mechanism for rapid insertion of GlyR in
the synaptic plasma membrane, a hypothesis that remains to be
confirmed. Here, we created an 1 construct, myc-Thr:: 1,
bearing a thrombin cleavage site connecting the N-terminal myc epitope
and the subunit (Fig. 1A). It was encoded by a cDNA
lacking the sequence corresponding to the mRNA 3' untranslated
region, which is thought to be responsible in most cases for the
dendritic mRNA localization (Gardiol et al., 2001, see references).
Therefore its synthesis most likely occurred in the somatic endoplasmic
reticulum only. This was a major advantage because protein detected at
the dendritic locations could only result from synthesis in the soma
followed by transport. This myc-Thr:: 1 construct was used
with the aim of trimming cell surface c-myc epitope tags from living
transfected cells to allow the selective visualization at the plasma
membrane of newly synthesized receptor. After 14-16 hr of expression,
the transfected cells were incubated at 19.5°C for 1 hr to
synchronize the post-Golgi traffic. This lower temperature prevents
exit from the TGN where secretory proteins accumulate, a treatment that has the advantage of avoiding a pharmacological perturbation of intracellular transport (Matlin and Simons, 1983; Griffiths et al.,
1985). The thrombin treatment and the temperature-induced block of TGN
exit were combined. They were followed by a restoration phase
obtained by raising the temperature to 37°C for periods ranging from
0 to 90 min (Fig. 1B). This procedure was aimed at monitoring the fate of tagged GlyR after the reappearance of the myc
epitope at the cell surface in a synchronized wave.
The recovery of cell surface expression of myc-Thr:: 1 in
transfected COS-7 cells subjected to this protocol is illustrated in
Figure 1 (C1-C4). A diffuse fluorescent labeling of
the plasma membrane was observed when living, untreated cells were
incubated with the anti-myc antibody before fixation (Fig.
1C1). This fluorescence was no longer detectable after
thrombin treatment (Fig. 1C2, time 0 of the restoration
phase). It was, however, progressively restored after warmup (Fig.
1C3,C4, times 15 and 60 min), indicating that transport to the plasma membrane was restored after the release of the
temperature block. Consistently, this was accompanied during the same
period by the redistribution of the intracellular myc epitope. As shown
in Figure 1D, myc-tagged subunits observed during the
restoration phase after a second thrombin treatment (see Materials and
Methods) migrated from the TGN located in the perinuclear region to
putative transport containers radiating away toward the cell periphery
(Fig. 1, compare D2, D3, D4). A
residual labeling of the TGN was often observed for up to 60 min after
transfer of the cells from 19.5 to 37°C. Nevertheless, the overall
distribution pattern, after a 60 min restoration phase, of the myc tag
protected from thrombin cleavage was similar to that of
myc-Thr:: 1 in untreated cells (Fig. 1, compare
D1, D4). The vast majority of myc-Thr:: 1 inserted into the cell membrane was most likely
derived from newly synthesized molecules because the c-myc epitope was barely detected outside of the TGN in blocked cells (Fig.
1D2, time 0 of the restoration phase). Together,
these results show that thrombin efficiently trimmed
myc-Thr:: 1 expressed at the cell surface and that
transport of newly synthesized subunits to the cell surface can be
selectively visualized.
Insertion of GlyR as microclusters in the plasma membrane
of neurons
Having established the resumption of plasma membrane insertion of
intact tagged GlyR after releasing the inhibition of exit from the TGN,
we applied the above procedure to neurons transfected 7-9 d after
plating. In a previous study (Meier et al., 2000, 2001) we had
established that, in neurons, homomeric GlyR assembled with myc-tagged
subunits was expressed at the cell surface. A patchy pattern of GlyR
distribution was observed when anti-myc antibody was reacted with
intact living cells at low (2°C) temperature without access to the
cell interior (Misek et al., 1984; Pfeiffer et al., 1985) to prevent
free diffusion of receptors in the membrane. It formed discrete
microclusters distributed over the somatodendritic surface that could
be observed as early as 4 hr after transfection at nonsynaptic loci.
With time they tended to form larger clusters associated with
postsynaptic gephyrin. The formation of GlyR clusters was
neuron-specific and was not observed in non-neuronal cells (COS-7)
cotransfected with gephyrin and GlyR subunits unable to interact with
gephyrin (Meier et al., 2000). In this case, immunolabeling of living
cells expressing high levels of cell surface GlyR did not lead to
receptor cluster formation, and GlyR remained diffusely distributed. We
had then hypothesized that the small clusters may represent kinetic
intermediates between newly cell surface-inserted and postsynaptic
GlyR. The use of the myc-Thr:: 1 construct was now aimed at
visualizing the first detectable form of GlyR at the surface of living,
unfixed cells (see Materials and Methods) and its localization.
Neurons were cotransfected with pC-myc-Thr:: 1 and pEGFP-N1
to compare the myc tag distribution at the cell surface with the entire
cell morphology outlined by GFP fluorescence. As observed for COS-7
cells, no cell surface myc tag labeling was observed after 1 hr of
thrombin treatment (Fig.
2A, time 0 of the
restoration phase). Cell surface expression of myc-Thr:: 1
occurred progressively during the restoration phase (Fig.
2B,C). It could be detected as
early as 7 min after its onset (data not shown) and, as illustrated here at 15 (Fig. 2B) and 60 (Fig. 2C) min.
With time, GlyR clusters could be detected farther away on neurites.
Diffuse staining of the myc tag was never detected on the cell surface
whatever the stages of the restoration phase. Instead,
myc-Thr:: 1 was always seen as forming microclusters (Fig.
2B,C), similar to those observed in
cells reacted with the antibody before thrombin treatment (Fig. 2A, inset). They were also similar to
those previously observed for tagged 1 and 2 GlyR subunits
lacking the thrombin cleavage site (Meier et al., 2000).
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Figure 2.
Cell surface GlyR clusters during the
restoration phase in neurons. Neurons were cotransfected with
pC-myc-Thr:: 1 and pEGFP-N1 and processed as described in
Figure 1C. Cell surface c-myc immunofluorescence is
shown superimposed on GFP fluorescence in treated cells fixed at 0 (A), 15 (B), and 60 (C) min of the restoration phase.
A, Inset, Expression of
myc-Thr:: 1 in a control neuron 16 hr after transfection.
B2-B5, C2-C5, Higher magnification of
regions outlined and numbered in B1, C1,
respectively. Note the initial appearance of c-myc immunoreactivity as
puncta (B, C, arrows) similar to those shown in the
inset in A. Scale bars: A,
10 µm; inset, 5 µm.
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It is worth noting that during the restoration phase very little
association of newly inserted GlyR with postsynaptic loci could be
observed. This is illustrated in experiments (Fig.
3A, arrows) in which the myc
tag was detected together with the vesicular inhibitory amino acid
transporter (VIAAT), taken as a marker of inhibitory presynaptic
boutons in synapses (Dumoulin et al., 1999). As shown after 30 min of
restoration, GlyR clusters were mainly extrasynaptic
(arrowheads). This extrasynaptic localization is consistent
with our previous results showing that postsynaptic accumulation of
transfected GlyR at inhibitory synapses was a progressive event taking
place over a 24 hr period (Meier et al., 2000). Nonsaturating
expression is suggested by the fact that, in transfected neurons, we do
not observe a first synaptic delivery followed by a subsequent
distribution to extrasynaptic areas. This indicates that newly
synthesized GlyR undergoes exocytosis mainly, if not exclusively, at
nonsynaptic plasma membrane domains.
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Figure 3.
Features of cell surface GlyR clusters
during the restoration phase. Neurons were treated as in Figure 2.
A, Relationships of cell-surface clusters of GlyR
myc-Thr:: 1 subunits to VIAAT immunoreactivity. Cell
surface c-myc (red) and VIAAT
(green) immunofluorescences are shown
superimposed, at high enlargement (thus pixelized), in cells fixed at
30 min of the restoration phase. Arrowheads, Nonsynaptic
myc immunoreactivity; arrows, examples of myc/VIAAT
colocalization. B, Surface area of myc-tagged GlyR
clusters. The surface area of peripheral clusters present on soma and
dendrites was determined using NIH version 1.52 software at the
indicated time point. Measured sizes did not differ significantly, and
the surface area could be averaged to 0.11 ± 0.01 mm2 (SEM; n = 120) during the
restoration phase. C, Absence of association of newly
inserted myc-tagged GlyR with clusters inserted in the plasma membrane
before thrombin treatment. Neurons were cotransfected with
pC-HA:: 1 and pC-myc-Thr:: 1 and
processed as described in Figure 2. Cell surface double
immunofluorescence staining of c-myc (red) and HA
(green) tags was performed after 60 min, as
indicated in Materials and Methods. Superimposition of both labels is
shown in C1 and C4, and HA and
c-myc-selective labeling is shown in C2 and
C3, respectively. C2-C4, Higher
magnification of regions outlined in C1. Note the
relatively low HA staining (arrowheads) in clusters of
myc-tagged 1 subunit (arrows) in comparison with that
of HA-positive, myc-negative clusters (thick arrows).
Scale bars: A, 1 µm; C1, 10 µm.
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A measure of the size of plasma membrane GlyR clusters at various time
points of the restoration phase for up to 90 min revealed a constant
surface area of ~0.11 ± 0.014 µm2 (Fig. 3B). This value is
close to the steady-state size (0.09 µm2) of HA-tagged 1 clusters not
associated with gephyrin in transfected neurons (Meier et al., 2000).
It should be noted that this labeling pattern of clusters is not
dependent on the antibody concentration reacted with the cooled, living
cells [e.g., 10 µg/ml (Meier et al., 2000) or 1 µg/ml (present
study)]. If the antibody was responsible for cluster formation, then
cluster size would vary greatly as a function of antibody
concentration. The surface areas that have been measured correspond to
equivalent disks of ~0.36 µm in diameter, a value above the
theoretical optical resolution of our microscope (100× objective,
numerical aperture 1.4 at 500 nm): 0.22 nm. Our measurements are
certainly biased at the low end by diffraction effects for clusters
smaller than the optical resolution. Yet this bias does not modify our
conclusion that the size of nonsynaptic clusters did not increase from
their time of appearance until 90 min of restoration. This size
invariance raised the following question. Did the myc-tagged 1
clusters originate from the association of new receptors with
pre-existing, trimmed 1 clusters, or did they form independently of
them? To address this point, the restoration phase was analyzed in
neurons transfected with equimolar amounts of pC-HA:: 1 and
pC-myc-Thr:: 1. After a 1 hr restoration, clusters of two
types existed at the cell surface, respectively bearing HA tag only or
both HA and myc tags (Fig. 3C1-C4). The latter clusters were expected because most newly inserted GlyR is likely homomeric (Meier et al., 2000) and randomly composed of myc- and HA-tagged 1 subunits. These newly inserted clusters, which could be
clearly identified by their myc tag staining (Fig. 3C3),
exhibited a lower HA tag staining as compared with pre-existing ones
bearing the HA tag only (Fig. 3C2). Very likely, lower
anti-HA antibody binding arose from steric hindrance revealed in this
particular case in which primary antibodies compete for topologically
equivalent antigenic sites. An important finding of this experiment
lies in the fact that newly inserted myc-labeled GlyR did not associate with the bright (pre-existing) clusters exclusively labeled with the HA
tag (Fig. 3C4). If pre-existing HA-tagged clusters
did not recruit newly inserted myc-labeled GlyR, then one could predict that their number was almost invariant during the 60 min restoration phase studied. Yet the average density of HA-positive, myc-negative GlyR clusters did not decrease from the onset (4.2 ± 0.2 clusters/µm2; n = 5) to
time 60 min (5.1 ± 0.2 clusters/µm2; n = 5) of
the restoration phase. This result favors the notion that newly
inserted myc-tagged GlyR did not populate clusters already containing
receptors. The above results also argue against an antibody-dependent
formation of receptor clusters in neurons. If the antibody induces
receptor aggregation, (1) the size of the clusters would be a function
of the increasing cell surface GlyR concentration during the
restoration phase and (2) the anti-HA antibody would induce the fusion
of pre-existing and newly inserted receptors that both possess the HA
tag. As a consequence, the formation of receptor clusters in
transfected neurons does not result from a progressive, time-dependent
association of newly inserted molecules. Together with the invariance
of cluster surface area, this shows that aggregation of receptors is
not a concentration-dependent process.
Altogether, these experiments indicate that newly synthesized GlyR
myc-Thr:1 is inserted in the plasma membrane at nonsynaptic loci
already forming small, discrete clusters.
Exocytosis of newly synthesized GlyR occurs in the somatic and
proximal dendritic plasma membrane
The early insertion of GlyR at the cell surface was always
observed on the soma and proximal dendritic segments. This suggested that the exocytosis of newly synthesized GlyR did not occur randomly over the somatic and dendritic compartments. To test this hypothesis, the kinetics of GlyR transport to the cell surface was scored by
counting receptor clusters present in the somatic and dendritic plasma
membrane at various stages after the release of the temperature block
and for up to 90 min. This was allowed by the invariant size of cell
surface clusters during the restoration phase. The replenishment of the
somatic and dendritic pools of receptors displayed distinct time
courses (Fig. 4A). The
transport of GlyR to the somatic surface was a biphasic process. The
initial and steep phase of the curve terminated ~30 min after the
37°C shift. It likely corresponded to the nearly synchronized
transport of receptors previously sequestered in the TGN (Griffiths et
al., 1985) and delivered with a half-time of ~15 min. This was
followed by a much slower transport phase. This reflected the
steady-state externalization rate of receptors synthesized during and
after the temperature-induced block. These kinetics are exactly what was expected from this experimental strategy. In comparison, cell surface GlyR clusters over dendrites could be detected as early as 5-7
min and increased steadily over the investigated 90 min restoration
phase. In dendrites, a rapid phase that would reflect the synchronized
wave of GlyR transport could not be detected. This indicated that
replenishment of cell surface GlyR populations in soma and dendrites,
respectively, involved distinct pathways.
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Figure 4.
Quantitative analysis during the restoration
phase. The mean number of cell surface myc-tagged GlyR clusters (±SEM)
from two separate experiments was determined from 7 to 90 min after the
19.5-37°C shift. A, Kinetics of cluster accumulation
in somatic and dendritic compartments (at least 8 neurons per time
point). B, Comparison of cluster numbers in dendrites as
a function of distance to soma. Plots of the counts obtained for 5 µm
length intervals on dendrites (n > 40) at the
indicated recovery time. C, Relative distributions of
clusters. Relative frequency
Ft/F15
over dendrite length is calculated as the ratio of frequency at time
t (Ft;
t = 7, 15, 30, 60, and 90 min) to frequency at 15 min (F15). t = 15 min is the half time for GlyR delivery from TGN (see Results).
D, Kinetics of GlyR replenishment in dendrites at
various distances (as indicated) from the soma. Counts at each distance
(spatial bin = 5 µm) are plotted on a logarithmic time scale.
A-D are from the same set of neurons.
|
|
The delivery of GlyR to dendrites was quantified more precisely by
measuring the distribution of clusters over individual dendrites at the
same time points of the restoration phase as above. The recovery of
cell surface GlyR expression was not homogenous in dendrites: at all
stages of the restoration the density of clusters per 5 µm length
intervals decreased from proximal to distal dendritic ends (Fig.
4B). After 7 min, all dendritic GlyR clusters were
localized within 20 µm of the cell body, whereas at 60 min, GlyR
clusters were found as far as 80 µm. This indicated that dendrites
were progressively populated by the receptor released by the somatic
TGN at the onset of the restoration phase. However, the analysis of the
frequency of receptor occurrence along dendrites showed that it varied
with the time elapsed after warmup, the frequency within the proximal
15-20 µm diminishing substantially while increasing in distal
segments. This is particularly illustrated by the curves obtained for
the relative frequencies (Fig. 4C) calculated as the ratio
of frequency at time t to that at 15 min, the time corresponding to
half delivery from the TGN (Fig. 4A). The negative to
positive transition in the curve slope from time points taken before
and after 15 min, respectively, indicated that GlyR clusters did not
insert randomly in dendrites. A random GlyR insertion-exocytosis,
arising from fusion events occurring evenly over the entire dendritic
plasma membrane, would give horizontal relative frequency curves (with
1 as ordinate). Therefore, the curves obtained here may reflect two
distinct processes taking place during the restoration phase: either a
shift from an early preferentially proximal to a late preferentially
distal exocytosis, or the redistribution of surface GlyR from proximal
to distal dendritic segments.
Together, these results indicate that newly synthesized GlyR delivered
from the TGN (1) undergoes early exocytosis in the cell body and the
initial portions of dendrites and suggests that (2) it is subsequently
delivered to distal regions of the dendrites.
Cell surface redistribution of newly synthesized GlyR to
distal dendrites
We next investigated the question of how GlyR clusters occur in
more distal portion of dendrites. Because GlyR clusters appeared concomitantly with, or immediately after, exocytosis, it could be
assumed that transport containers of the exocytic pathway contained enough receptor to allow their visualization, as observed in COS-7 cells. Moreover, as shown in Figure 4A, the number of
GlyR clusters delivered to dendrites within 60 min is close to that
present at the surface of the soma (130-140 cluster per cell).
Therefore, after 60 min, the presence of a fraction of the
corresponding intracellular containers, if any, was expected to be
detected in dendrites within 60 µm of soma (Fig.
4B). The restoration phase was therefore initiated in
cells processed as in Figure 2 and followed by a second thrombin
digestion before fixation (as in Fig. 1D). No cell
surface myc-epitope labeling was observed on living cells after the
second thrombin treatment (data not shown), indicating that the removal
of the tags when performed at the end of a restoration phase was as
efficient as in the first treatment (Figs.
1C2,D2, 2A). This allowed the
selective visualization of intracellular myc-tagged GlyR protected
during the last thrombin digestion. Surprisingly, under these
conditions, no significant intracellular labeling (corresponding to
internalized receptors) could be detected in dendrites at the end of
the 19.5°C step. Only somatic and perinuclear myc antigenicity could
be seen at the onset of the restoration phase; mainly outlining TGN and
to some extent late endosomal cisternae (Fig.
5A2, time 0 of the restoration
phase). Later, although myc-tagged GlyR leaving the TGN could be
detected in the soma, no staining of the myc epitope could be observed
in dendrites at either early or late restoration times. The
distribution of intracellular myc tag shown after 60 min is
representative of all stages of the restoration phase (Fig. 5B2). This indicated that in these experiments,
intracellular transport of newly synthesized GlyR in dendrites was not
a predominant pathway. As a consequence, replenishment of the dendritic
pool of GlyR mainly, if not totally, occurred via redistribution by diffusion of initially somatic cell surface clusters.
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|
Figure 5.
Redistribution of intracellular myc-tagged GlyR
during the restoration phase. Cells were cotransfected with
pC-myc-Thr:: 1 and pEGFP-N1. The c-myc epitope was revealed
as in Figure 2B by immunostaining of cells after
a second thrombin treatment then fixed and permeabilized at 0 (A1, A2) and 60 (B1, B2) min after the
19.5-37°C shift. A1, B1, GFP
fluorescence; A2, B2, c-myc
immunoreactivity. Note the appearance of putative transport containers
(arrows) in B2. Scale bar, 10 µm.
|
|
Given the redistribution of GlyR clusters from a somatic pool to a
dendritic one, the appearance of dendritic clusters could be postulated
to follow first-order kinetics. Numbers of clusters over time were thus
determined at various positions over dendrites up to 40 µm from soma.
Linear restoration curves were obtained by plotting cluster numbers on
a logarithmic time scale (Fig. 4D). Using the time
obtained from the curves to reach a defined position, the average
linear velocity of GlyR clusters in dendrites was calculated as 3.3 µm/min. The apparent diffusion coefficient D, was calculated by
applying Fick's second law:
assuming a constant dendritic section, using n as the
number of clusters per 5 µm length interval at increasing distances (x) from soma and at various times (t) of the
restoration phase. D computed from the data of Figure 4,
B and D, was found to be 2.76 × 102 ± 1.7 × 102
µm2/sec (mean ± SEM), a value
close to the diffusion coefficient that we obtained using optical
tracking of GlyR in transfected neurons (2.81 × 102 ± 7 × 103
µm2/sec) (Meier et al., 2001). Although
an approximation of the GlyR redistribution process, these results are
consistent with the notion that dendritic clusters arise from initially
somatic or more proximal ones by diffusion.
Altogether, these results indicate that (1) the intracellular route for
GlyR delivery to dendrites is a minor pathway and (2) dendritic
localization is mainly achieved by cell surface diffusion of receptor
initially inserted in the somatic compartment.
| |
DISCUSSION |
We analyzed in cultured neurons the export of newly synthesized
GlyR from the TGN to the plasma membrane, to define its exocytosis site. The basis of this study is the observation that exogenous GlyR is
gradually positioned into gephyrin-enriched postsynaptic domains over
the neuronal somatodendritic surface (Meier et al., 2000). We therefore
postulated that the mechanisms required for proper targeting of GlyR
were not saturated in the experiments performed here in neurons
exhibiting intensive synaptogenesis (Béchade et al., 1996).
Our strategy was to transfect cells with a recombinant GlyR
subunit bearing an exocytoplasmic, proteolytically cleavable tag. Two
combined mild treatments created an observable synchronized exocytic
wave: (1) a transient, reversible block of exit from the TGN (Matlin
and Simons, 1983; Griffiths et al., 1985; Hughson et al., 1988) and (2)
a selective removal of extracytoplasmic tags using thrombin digestion.
The restoration of cell surface expression of the tag, corresponding to
the resumption of post-Golgi transport, was monitored by
immunofluorescence microscopy.
Newly synthesized GlyR diffuses as clusters from somatic to
dendritic compartments
We show that exocytosis of newly synthesized GlyR mainly occurs at
nonsynaptic sites in the cell body and the initial portion of dendrites
followed by receptor diffusion to distal regions of the dendritic
plasma membrane. Different time courses characterize the appearance of
GlyR in the somatic and dendritic areas. Because a wave of vesicular
transport was created between the Golgi complex and the plasma membrane
(Griffiths et al., 1985), a two-phase process should account for the
recovery of cell surface GlyR over the entire somatodendritic
compartment. This is not the case, indicating that somatic and
dendritic domains are not equivalent sites for the rapid and early
delivery of exocytic carriers of GlyR. Therefore, we conclude that,
because of the lack of detectable transient intracellular flow of
transport containers in dendrites, the somatic membrane (and to some
extent the initial dendritic segment) is the major acceptor for
exocytic fusion.
Our results show that GlyR subsequently populates dendrites, in a phase
during which no association with synapses was noted, via diffusion of a
receptor pool initially located in the soma. Interestingly, the
analysis of GlyR distributions in dendrites as a function of time
revealed first-order kinetics, reinforcing the idea of a
precursor-product relationship between somatic and dendritic GlyR
molecules. This transition is characterized by a diffusion coefficient
close to that obtained by single particle tracking in transfected
neurons (Meier et al., 2001) and to those of other diffusive membrane
proteins (Saxton, 1997; Saxton and Jacobson, 1997; Kusumi,
1999).
A striking feature of homomeric GlyR expressed in neurons is its
ability to form minute clusters independently of detectable interaction
with gephyrin (Meier et al., 2000). However, GlyR was shown to
progressively populate plasma membrane postsynaptic domains where it
colocalizes with endogenous gephyrin (Meier et al., 2000). The present
results show that these clusters form very early after arrival of GlyR
in the plasma membrane. Their almost uniform size does not vary with
time, although the overall concentration of receptor molecules at the
cell surface increases, suggesting that they form stable GlyR
assemblies that do not undergo aggregation via a
concentration-dependent process. This is confirmed by the observation
that newly synthesized GlyR was not associated with clusters that had
been inserted in the plasma membrane before the temperature-induced
arrest in the TGN. Our previous results combined with those presented
here indicate that extrasynaptic minute GlyR clusters represent true
kinetic intermediates between newly synthesized and postsynaptic GlyR.
Whether these complexes form before or after exocytosis of transport
carriers is unknown. Neuron-specific properties of GlyR may govern its
clustering (Meier et al., 2000). This may include (1) lateral or
vertical interaction with proteins triggering the formation of stable
receptor-enriched domains and (2) post-translational modifications
allowing either recognition of partner proteins or homophilic
interactions. With regard to the participation of cytoplasmic proteins,
this event could take place as early as the Golgi complex. Indeed, the
spectrin- or ankyrin-based Golgi-associated membrane skeleton very
likely promotes the formation of protein microdomains within the TGN,
while contributing to vesicle transport (Beck and Nelson, 1996;
Devarajan et al., 1996; Beck et al., 1997). However, homophilic
association would be analogous to the kin recognition phenomenon
applying to Golgi enzymes (Nilsson et al., 1994).
Implications for GlyR targeting in neurons
As previously proposed (Craig et al., 1994), accumulation of
receptors in synapses may result from a unspecified fusion of post-Golgi vesicles with the plasma membrane where receptors could diffuse before retention in postsynaptic sites. Another mechanism would
correspond to the direct targeting via specific transport vesicles
after sorting in the TGN. Our present and previous (Meier et al., 2000)
results show that GlyR at the time of, or shortly after, plasma
membrane insertion is not found in axons and not associated with
synapses. Instead, the present work shows that it can diffuse from
proximal to distal dendritic regions, indicating that it is not
stabilized at a specific locus. Moreover, we showed that it can
nevertheless be incorporated into synapses (Meier et al., 2000).
Altogether, our data strongly suggest that GlyR is routed to synapses
via the first mechanism. This implies that two types of targeting
information are required: one for sorting into vesicles destined for
the somatic plasma membrane and another for retention in postsynaptic
domains. As a consequence, GlyR is not necessarily segregated in the
TGN from other somatodendritic proteins. Whether this
diffusion-retention model holds for the targeting of other dendritic
receptors will require further investigations. A plausible prediction
of the model would be that several distinct molecules, including other
receptors, are transported in GlyR-containing transport carriers. A
diffusion-retention model posits that vesicular traffic is not
vectorial. Because GlyR never appeared in axons, it raises another
question: is GlyR vectorially transported to the somatodendritic domain?
The vectorial transport pathway, first described in polarized cells for
the construction of apical and basolateral domains, either begins with
the formation of Golgi-derived transport vesicles segregating specific
proteins (Rodriguez-Boulan and Nelson, 1989; Keller and Simons, 1997),
or involves a transcytosis step with endosomal sorting if proteins are
first delivered to a distinct plasma membrane domain (Bartles et al.,
1987; Matter et al., 1990). These pathways also account for neuron
polarization (Winckler and Mellman, 1999). Examples of direct
routing of somatodendritic proteins sorted in the TGN, and excluded
from axons, are provided by the polymeric Ig (de Hoop et al., 1995),
the transferrin (West et al., 1997), the low-density lipoprotein (Jareb
and Banker, 1998) receptors, and the GLYT1 isoform of the glycine
transporter (Poyatos et al., 2000). Signals responsible for vectorial
transport were also proposed for the neurotransmitter receptors mGluR2
(Stowell and Craig, 1999) and GluR1 (Ruberti et al., 2000). Plausibly, such signals, still to be identified, would also exist in GlyR leading
to exclusion from axons because, as is the case for the above proteins
when overexpressed in neurons, in our present or previous work GlyR was
never expressed in axons (Meier et al., 2000). GlyR targeting, using
two types of sorting information, would thus be similar to that of
prominin, which is enriched in apical microvillar subdomains of
epithelial cells (Corbeil et al., 1999). Surprisingly, however,
exocytosis of GlyR did not occur significantly in dendrites (although
synapses are also located in this compartment). This distinguishes its
insertion-retention process from those of other selectively retained
proteins: the Na+/K+-ATPase
(Hammerton et al., 1991; Mays et al., 1995a,b) and the 2B-adrenergic receptor (Wozniak and Limbird, 1996).
The lack of vesicular transport of GlyR in distal regions of dendrites
is consistent with the notion that the specific retention of an
otherwise diffusive protein is sufficient for synaptic localization without any intracellular routing over long distances. The
diffusion-retention model proposed for GlyR thus points to the key
role of the retention signal and in turn to the anchoring role of
gephyrin. It remains to be investigated whether a diffusion-retention
process can be extrapolated to other synapses or ion channel-enriched
domains (Scannevin et al., 1996; Zhou et al., 1998). This mechanism has already been proposed for the neuromuscular junction, because diffusing, mobile acetylcholine receptors are progressively inserted and stabilized at postsynaptic loci during synaptogenesis by the anchoring protein rapsyn (Kuromi et al., 1985; Froehner, 1993). The
assemblies of cytoplasmic and transmembrane proteins found in
inhibitory (Kirsch, 1999; Kneussel and Betz, 2000, see references) and
excitatory (Kim and Huganir, 1999, see references) synapses would
constitute multivalent binding sites recruiting receptors within
postsynaptic loci. On the one hand, their availability and saturation,
not required for initial targeting, would control the rate-limiting
step of postsynaptic capture. This hypothesis is supported by the
observation that dendritically delivered receptors are not always
clustered in synapses (Stowell and Craig, 1999; Ruberti and
Dotti, 2000). On the other hand, receptor tethering could likely be
controlled at the level of the plasma membrane and not at the
exocytosis step (as in the direct targeting model). This could be
achieved by acting on an equilibrium between diffusive and immobilized
receptor molecules. Such a hypothesis is favored by the demonstration
that cell surface GlyR can rapidly alternate between diffusive and
confined states, the frequency of the latter being increased by
gephyrin (Meier et al., 2001).
| |
FOOTNOTES |
Received Feb. 22, 2001; revised April 25, 2001; accepted April 30, 2001.
This work was supported by grants from the Institut de Recherche sur la
Moelle Epinière. M.R. was supported by Institut National de la
Santé et de la Recherche Médicale and the Medical Research Council of Canada. J.M. was supported by fellowships from Fonds der Chemischen Industrie (0653082), Deutscher Akademischer
Austauschdienst (D/98/03816), and Centre International des Etudiants et
Stagiaires (242708G).We thank Drs. B. Dargent and D. Choquet for
helpful comments and criticism and for reading this manuscript. We
thank the Vector Core of the University Hospital of Nantes supported by
the Association Française contre les Myopathies for
providing the Ad.RSV.nlsLacZ.
Correspondence should be addressed to Christian Vannier, Laboratoire de
Biologie Cellulaire de la Synapse Normale et Pathologique, Institut
National de la Santé et de la Recherche Médicale U497, Ecole Normale Supérieure, 46 rue d'Ulm, 75005 Paris, France. E-mail: vannier{at}wotan.ens.fr.
| |
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ABSTRACT
INTRODUCTION
