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The Journal of Neuroscience, September 1, 1998, 18(17):6892-6904
N-Cadherin Redistribution during Synaptogenesis in
Hippocampal Neurons
Deanna L.
Benson1 and
Hidekazu
Tanaka2
1 Fishberg Research Center for Neurobiology and
2 Brookdale Center for Developmental and Molecular Biology,
Mount Sinai School of Medicine, New York, New York 10029
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ABSTRACT |
Cadherins are homophilic adhesion molecules that, together with
their intracellular binding partners the catenins, mediate adhesion and
signaling at a variety of intercellular junctions. This study shows
that neural (N)-cadherin and  -catenin, an intracellular binding
partner for the classic cadherins, are present in axons and dendrites
before synapse formation and then cluster at developing synapses
between hippocampal neurons. N-cadherin is expressed initially at all
synaptic sites but rapidly becomes restricted to a subpopulation of
excitatory synaptic sites. Sites of GABAergic, inhibitory synapses in
mature cultures therefore lack N-cadherin but are associated with
clusters of -catenin, implying that they contain a different classic
cadherin. These findings indicate that N-cadherin adhesion may
stabilize early synapses that can then be remodeled to express a
different cadherin and that cadherins systematically differentiate
between functionally (excitatory and inhibitory) and spatially distinct
synaptic sites on single neurons. These results suggest that
differential cadherin expression may orchestrate the point-to-point
specificity displayed by developing synapses.
Key words:
N-cadherin; -catenin; synaptogenesis; synaptic
junctional complex; presynaptic membrane; postsynaptic membrane; PSD; wnt/wingless
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INTRODUCTION |
Cadherins comprise an extensive
family of type I glycoproteins having large, extracellular N-terminal
domains and smaller, intracellular C-terminal domains (Geiger and
Ayalon, 1992 ). The "classic" cadherins were the first to be
discovered and are named according to where they were found initially,
E-cadherin from epithelial cells, N-cadherin from neural epithelium,
and P-cadherin from placenta (Hatta and Takeichi, 1986; Geiger and
Ayalon, 1992; Grunwald, 1996); but each of these proteins has
subsequently been shown to have a much broader tissue distribution
(Geiger and Ayalon, 1992). The adhesive properties of classic cadherins
are undisputed. It has been stated that "as long as cadherins are
functioning, other adhesion systems have little effect on cell-cell
adhesion" (Takeichi, 1991). In the presence of calcium, they bind
tightly and usually homophilically to one another (Nose et al., 1990; Amagai et al., 1992) through a complex set of interactions occurring in
the first (EC1) of five extracellular domains (Nose et al., 1990;
Overduin et al., 1995; Shapiro et al., 1995). Adhesion also requires
the C-terminal cytoplasmic domain that is highly conserved among the
cadherins and serves to link extracellular adhesion with actin
cytoskeleton via the catenin polypeptides ( -, -, and  -)
(Nagafuchi and Takeichi, 1988, 1989; Ozawa et al., 1990; Knudsen et
al., 1995; Rimm et al., 1995), two of which ( and ) have been
localized to the synaptic junctional complex and are known to associate
with multiple cadherin subtypes (Uchida et al., 1996). At this
time, almost 40 cadherin and cadherin-related molecules have been
reported in the brain, supporting their potential for adhesive
specificity (Ranscht and Dours-Zimmerman, 1991; Suzuki et al., 1991;
Sano et al., 1993; Sugimoto et al., 1996; Shibata et al., 1997).
The morphology of cadherin-based adherens junctions is remarkably
similar to that of synapses (Peters et al., 1991). Consistent with this, N-cadherin is concentrated in isolated postsynaptic densities (Beesley et al., 1995) and is localized to synaptic junctional complexes, where it has been suggested that it is
instrumental in the targeting and "locking in" of synaptic
connections (Fannon and Colman, 1996; Uchida et al., 1996; Inoue and
Sanes, 1997). These data strongly suggest that the underlying
mechanisms by which pre- and postsynaptic membranes adhere to one
another in the CNS may be the same as those that generate intercellular
adhesion in other, non-neural tissues. According to this model (Fannon and Colman, 1996; Uchida et al., 1996), synaptic specificity is generated by the differential expression and distribution of
cadherins.
In this study, using cultured hippocampal neurons as a model system, we
determine when cadherins become associated with synapses, whether they
are present at all synapses, and whether N-cadherin segregates to
excitatory or inhibitory synaptic sites. The advantage of this system
is that neurons can be grown at a very low density such that neuronal
somata and dendrites are often completely isolated from one another and
synapses and their subcellular distribution can be readily resolved by
conventional light or confocal microscopy (Goslin and Banker, 1991).
Our results indicate that early in synaptogenesis, N-cadherin is
present at all synapses between hippocampal neurons but rapidly becomes
restricted to excitatory synapses, a distribution that is maintained in
mature brain in vivo.
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MATERIALS AND METHODS |
Neuron cultures. Cell cultures were prepared from
hippocampi of embryonic day 18 Sprague Dawley rats as described
previously (Goslin and Banker, 1991; Benson et al., 1994). Cells were
dissociated by treatment with 0.25% trypsin for 15 min at 37°C
followed by trituration through a Pasteur pipette. Cells were plated at
a density of 3600 cells/cm2 on
poly-L-lysine-coated coverslips in minimum essential media (MEM; Life Technologies, Gaithersburg, MD) containing 10% horse serum.
After ~4 hr, when cells had attached, coverslips were transferred to
dishes containing a monolayer of cortical astroglia, where they were
maintained for up to 5 weeks in MEM containing N2
supplements (Bottenstein and Sato, 1979), sodium pyruvate (1 mM), and ovalbumin (0.1%).
Immunoblots and antibody controls. The N-cadherin and
-catenin antibodies used in this study had not been characterized
previously in rat brain. Homogenates were prepared from hippocampal
neurons that had been grown in culture for 3 weeks by rinsing cells in PBS and then solubilizing them in homogenization buffer containing 20 mM tetrasodium pyrophosphate, 20 mM sodium
phosphate, 1 mM magnesium chloride, 0.5 mM
EDTA, 300 mM sucrose, 8 µM benzamidine, 10 µM iodoacetamide, 0.011 µM leupeptin, 0.007 µM pepstatin A, 0.23 mM PMSF, and 76.8 nM aprotinin. Samples were sonicated briefly, centrifuged
for 5 min at maximum speed on a microfuge, and stored at  20°C.
Thawed samples (5 µg) were fractionated on 7.5% SDS-polyacrylamide gels and transferred to polyvinylidene difluoride paper. Blots were incubated with either mouse monoclonal anti-N-cadherin, an antibody directed against the C-terminal intracellular domain of
N-cadherin (13A9; gift from K. Knudsen Lakenau Medical Research Center) (Knudsen et al., 1995), or mouse anti--catenin (Zymed, San
Francisco, CA).
Immunostaining. Immunostaining was performed as described
previously (Benson et al., 1994) using the following primary
antibody(ies) diluted in 1% BSA in PBS at 4°C overnight: guinea pig
polyclonal or mouse monoclonal anti-N-cadherin; anti-GAD65
(monoclonal antibody GAD6; Developmental Studies Hybridoma Bank)
(Chang and Gottlieb, 1988); anti-synaptophysin [Boehringer Mannheim,
Indianapolis, IN (mouse) or Zymed (rabbit)]; anti-MAP2 (monoclonal
antibody AP14; gift from E. Torre, University of Virginia)
(Binder et al., 1986); anti-phosphorylated NF-H/M
(monoclonal antibody SMI-31; Sternberger Monoclonals, Baltimore,
MD); anti--catenin (Zymed); and anti-GluR1 and anti-postsynaptic
density (PSD)-95 (Upstate Biotechnology, Lake Placid, NY).
Antibody binding was visualized by incubating cells either with a
biotinylated secondary antibody, followed by fluorescein-labeled streptavidin (both from Vector Laboratories, Burlingame, CA), or with
Texas Red-labeled secondary antibodies (Vector Laboratories). For all
studies in which two antibodies were used simultaneously, staining was
compared with that obtained in cultures that were incubated with a
single primary antibody and with cultures incubated with different
combinations of secondary antibodies.
Mice were deeply anesthetized and then perfused transcardially with 4%
paraformaldehyde in PBS as described previously (Benson et al., 1992).
A tissue block from monkey hippocampus was kindly provided by J. Morrison (Mount Sinai School of Medicine). Sections were cut on a
vibratome at a setting of 50 µm, and free-floating sections were
processed for immunocytochemistry as described above.
Microscopy and analysis. Localization of
immunocytochemically identified proteins was assessed by conventional
or confocal microscopy. For confocal microscopy, both single optical
sections and "compressed" series (projections) of z-axis
optical sections were used to compare localization of two labels. Most
of the data are presented as projections of 3-30 optical sections
(3-9 sections through processes and 16-30 through somata) varying in
width from 0.1 to 0.5 µm. Figure legends indicate single sections as
well as variations in these parameters. Data obtained from two channels simultaneously using a dichroic beam splitter were compared with data
obtained sequentially using one laser line to ensure that emission
spectra were clearly separated. Colocalization was assessed on two
different confocal microscopes: a Zeiss LSM 410 using a 63×,
1.4 numerical aperture (NA) oil immersion objective, an Ar/Kr laser, a red-reflecting dichroic beam splitter, and filters  575-640 and 515-540, and a Leica TCS 4D using a 100×, 1.4 NA oil
immersion objective, an Ar/Kr laser, a red-reflecting dichroic beam
splitter, and filters BPFITC and OG590. The degree to which the
labels offset one another by error intrinsic to the microscope was
determined in N-cadherin-immunolabeled preparations simultaneously
tagged with FITC and Texas Red. By the use of the Zeiss confocal, green was offset from red 1 pixel at an angle of ~45° in single images and 0.5 pixel at the same angle in projected images. By the use of the
Leica confocal, there was a fraction of a pixel offset at 135° that
could be detected in both single and projected images. Given the far
greater degree of pixel overlap when comparing colocalization of two
labels, the image overlap was not altered post hoc.
Brightness and contrast settings for each label in double-labeled
preparations were kept within close range of one another. The area of
labeled puncta was measured using National Institutes of Health Image. Threshold intensity was set to include for measurements only puncta. Although user-determined thresholds for quantitative analysis might be
expected to yield a high degree of variability, we have found
"thresholded" data to be very consistent (Gazzaley et al., 1997).
GAD and N-cadherin codistribution was quantified on at least 10 neurons
from two preparations at each time point presented. GAD and N-cadherin
immunoreactive puncta were mapped separately on single neurons using a
63× oil immersion objective on a Zeiss Axiophot (conventional)
microscope, and the maps were aligned using NeuroZoom (a set of
software programs for quantitative microscopy developed via a
collaboration between Scripps Research Institute and Mount Sinai School
of Medicine).
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RESULTS |
Localization and specificity of N-cadherin and -catenin
antibodies in rat hippocampal neurons
In immunoblots from homogenates of cultured rat hippocampal
neurons, mouse N-cadherin antibody identified a single band of ~130
kDa, and -catenin antibody identified a single band of ~100 kDa,
similar to what has been described for the identification of each
protein in other species or with different antibodies (Fig.
1A). In cultured
neurons, immunocytochemical localization of mouse N-cadherin was
compared directly with localization of a guinea pig polyclonal
N-cadherin antibody in double-labeled preparations. Polyclonal antibody
labeling was more intense than monoclonal, but the two labels
overlapped completely (Fig. 1B,C). When N-cadherin polyclonal antibody was preincubated with a peptide fragment corresponding to the domain against which it was made, all
specific labeling was eliminated (Fig. 1D-G).
Together these data indicate that the N-cadherin and -catenin
antibodies used in this study were completely specific.
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Figure 1.
Localization and specificity of N-cadherin and
-catenin antibodies. A, Western blots of homogenates
from 17-d-old cultured hippocampal neurons incubated with monoclonal
antibody against N-cadherin (N-cad; left)
or -catenin (-cat; right) are
shown. Size standards are indicated on the left.
B, C, Extracellular
(B) and intracellular (C)
domain-specific antibodies against N-cadherin colocalize in
double-immunolabeled preparations of cultured hippocampal neurons.
D, F, Preadsorbed polyclonal antibody
yields no specific immunolabeling (F) compared
with control (D). E,
G, Corresponding phase-contrast photomicrographs are
shown. Scale bars: B, C, 4 µm;
D-G, 35 µm.
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N-cadherin is localized to developing synapses
Hippocampal neurons cultured at low density were used to examine
the localization of N-cadherin at the earliest stages of neuron
development and synapse formation. Before axonal outgrowth, diffuse
N-cadherin labeling was observed in cell somata and minor processes
that also contained small, immunoreactive puncta (Fig. 2A). After axonal
outgrowth (12-36 hr after plating), N-cadherin-labeled puncta were
more abundant in axons that could be identified by their longer length
and finer caliber, but diffuse N-cadherin labeling remained in both
cell somata and young dendrites (Fig. 2D,F). Identification of
axons was confirmed in some preparations by coimmunolabeling cultures
with an axonal marker SMI-31 that recognizes phosphorylated
neurofilament triplet proteins (data not shown). N-cadherin puncta were
only occasionally concentrated within axonal growth cones where they
lined the leading edge of lamellipodia but did not invade filopodia
(Fig. 2G). Thus, N-cadherin is present within both pre- and
postsynaptic compartments before synapses develop, and the diffuse
labeling may represent a locally recruitable pool of cadherins that
would be rapidly accessible for junction formation (Colman, 1997).
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Figure 2.
N-cadherin is present in axons and dendrites
before synaptogenesis. Fluorescence photomicrographs showing N-cadherin
(A, D, G) and
synaptophysin (B, E) immunolabeling
alongside corresponding phase-contrast photomicrographs
(C, F, H) during
early stages of neuron development are shown. Before axonal outgrowth,
N-cadherin- (A) and synaptophysin-
(B) labeled puncta are distributed throughout the
cell soma and minor processes (C). After
polarization, N-cadherin labeling (D) is detected
in both the axon (arrow) and dendrites, whereas in the
same neuron, synaptophysin labeling is polarized to the axon
(E; arrow). Both labels are detected in
soma (D, E). In G and
H, N-cadherin is concentrated at the lamellipodial edge
of a particularly large growth cone (arrow). Scale bars:
A-F, 18 µm; G, H, 11 µm.
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The relationship of N-cadherin puncta to synapses was determined in
neurons double-immunolabeled for N-cadherin and synaptophysin, a
synaptic vesicle protein concentrated in presynaptic terminals (Navone
et al., 1989; Fletcher et al., 1994). Before synapse formation (the
first 2 d in culture), synaptophysin-labeled vesicles did not
appear to be localized particularly with N-cadherin puncta (Fig.
2B,E), but at the onset of
synaptogenesis (3 d in culture), synaptophysin-labeled clusters were
colocalized with N-cadherin-labeled puncta (Fig.
3A-C), and cytoplasmic
N-cadherin labeling rapidly disappeared. In high magnification confocal
images, there was most commonly a central region of colocalization
flanked on one side by a rim of synaptophysin label and on the other by
a rim of N-cadherin label. The area occupied by N-cadherin puncta
appeared to be larger than that occupied by synaptophysin boutons (Fig. 3C, inset), but the difference was not
significant (p = 0.34). Nearly all N-cadherin
puncta were labeled for synaptophysin, and those puncta lacking
synaptophysin were very small, similar to those seen before
synaptogenesis, and were presumed to be nonsynaptic puncta adherens.
Synaptophysin accumulations clearly smaller than those that were
"synaptic" (Fletcher et al., 1991) lacked N-cadherin.
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Figure 3.
Synaptic localization of N-cadherin. Confocal
images show N-cadherin (green) and synaptophysin
(red) immunolabeling separately and overlaid in which
regions of colocalization that appear yellow.
A-C, In 5-d-old neurons, single optical sections show
all N-cadherin-labeled puncta (A; green)
contain synaptophysin label (B; red).
When images are overlaid (C), the close
association of N-cadherin and synaptophysin is readily apparent with
each complex having a central area of colocalization
(yellow). The synaptic complex (indicated by the
arrowhead) is presented at higher magnification
in each inset. D-F, By 14 d, most
N-cadherin puncta (D; green) remain
associated with synaptophysin boutons (E;
red), but some synaptophysin boutons
(arrow) lack N-cadherin (F). The
larger size of green N-cadherin puncta and their
relationship with red synaptophysin-labeled boutons can
be seen in the higher magnification inset of the
synaptic complex (indicated by the arrowhead) in
D-F as well as in G and
H. G-H,
N-cadherin appears to partially enclose synaptophysin labeling.
I-J, Figures illustrate the differences between
synaptophysin boutons that do not contain N-cadherin
(arrows) but are close to those that are colocalized
with N-cadherin (asterisks). Scale bars:
A-C, 4 µm (insets, 1 µm);
D-F, 11 µm (insets, 1 µm);
G, 1 µm; H, 1.3 µm; I,
0.7 µm; J, 0.8 µm.
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Between 1 and 2 weeks in culture, an increasing number of
synaptophysin-labeled boutons lacked corresponding N-cadherin puncta, but the vast majority of N-cadherin-labeled puncta continued to be
colocalized with synaptophysin (Fig. 3D-F). Single-
and double-labeled puncta were distributed along single dendrites. In
projected confocal images, a clear pattern of colocalization emerged.
The area occupied by N-cadherin puncta was significantly larger than
that occupied by synaptophysin boutons (0.44 ± 0.03 vs 0.28 ± .04 µm2; p < 0.005), and the
region of colocalization with synaptophysin occurred over a central
common zone. The range of configurations varied, but in all cases
examined and through all angles of rotation, N-cadherin label appeared
to overlap and usually surround synaptophysin-labeled clusters (Fig.
3D-J). Synaptophysin boutons lacking N-cadherin were
easily distinguished even when they occurred close to N-cadherin puncta
(Fig. 3I,J). The most likely
interpretation for this localization pattern is that N-cadherin and
synaptophysin are colocalized in the presynaptic side of the synaptic
junctional complex and that N-cadherin is also distributed
postsynaptically (see also Fig. 7). Together, these data indicate that
in hippocampal neurons all early synapses are associated with
N-cadherin, but after 7 d, a growing population of synapses lose
N-cadherin and/or develop in the absence of N-cadherin.
N-cadherin is lost from inhibitory synapses but retained at
excitatory synapses in culture and in situ
To investigate whether N-cadherin-negative and -positive synapses
in older cultures corresponded to inhibitory and excitatory synapses,
we double-immunolabeled neurons for N-cadherin and markers for
inhibitory (GABAergic) and excitatory (glutamatergic) synapses, which
together comprise the entire repertoire of synaptic interactions found
in cultured hippocampal neurons.
GABAergic synaptic boutons were identified using antibodies against
glutamic acid decarboxylase (GAD) (Ribak, 1978; Benson et al., 1994;
Benson and Cohen, 1996). Up to 7 d in culture, nearly all
GAD-labeled boutons contained N-cadherin (Fig.
4A-D). At high magnification, N-cadherin puncta and GAD-labeled boutons colocalized over a large central region similar to what was observed for N-cadherin and synaptophysin at early ages (compare Figs. 4B-D,
3A-C). However, after 7 d, the number of GAD- and
N-cadherin-labeled boutons declined such that, by 17 d, virtually
no GAD-labeled boutons contained detectable N-cadherin (Fig.
4E-H). The timing of this shift in N-cadherin
localization was determined by calculating the percentage of GABAergic
synapses containing N-cadherin label for at least 10 neurons in two
culture preparations at several time points (Fig.
5). The results indicate that,
surprisingly, N-cadherin is present at all early synapses but becomes
rapidly and selectively restricted to non-GABAergic and therefore
excitatory synapses. Early GABAergic synapses associated with
N-cadherin must be selectively eliminated, or N-cadherin must be
removed from GABAergic synapses. Interestingly, at intermediate time
points, very faint N-cadherin label was occasionally detected at some
GABAergic synaptic sites. These synapses were counted as N-cadherin
negative because the labeling intensity was too low to detect using
thresholds similar to those used for the area measurements described
above but may represent a transitional state in which N-cadherin is
gradually lost from GABAergic synapses.
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Figure 4.
N-cadherin is lost from inhibitory synapses.
Confocal images show low and high magnification images of N-cadherin
(green) and GAD
(purple) immunolabeling separately and
overlaid where regions of colocalization appear white.
A-D, At 7 d in culture, low
(A) and high (B-D)
magnification images show all GAD-labeled boutons associated with
N-cadherin puncta. Synaptic complex indicated by an
arrowhead is shown at higher magnification in each
inset (B-D) where a large area of
colocalization appears white in overlay.
E-H, In contrast, both low (E)
and high (F-H) magnification images indicate
that by 17 d in culture no GAD-labeled synapses contain
N-cadherin. Scale bars: A, 25 µm;
B-D, 5 µm (insets, 1 µm);
E, 12 µm; F-H, 7 µm.
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Figure 5.
Rate of N-cadherin loss from GABAergic synaptic
sites. The bar graph illustrates the percentage of GAD-labeled boutons
containing N-cadherin label at different stages of development. The
percentage drops sharply between 7 and 9 d and then continues to
drop more slowly to nearly zero by 17 d in culture.
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The double-labeling experiments strongly suggest that N-cadherin in
older neurons is associated with asymmetric, glutamatergic synapses. To
address this, we double-immunolabeled neurons 17 d or older for
N-cadherin and PSD-95/SAP90, a membrane-associated guanylate
kinase concentrated within asymmetric postsynaptic densities in
forebrain (Hunt et al., 1996), or GluR1, an AMPA-type glutamate receptor subunit that clusters opposite glutamate terminals (Craig et
al., 1994). N-cadherin puncta were associated with both PSD-95-labeled densities and with GluR1-labeled clusters (Fig.
6), many of which were localized on
dendritic spines. Some N-cadherin puncta were unlabeled in both cases.
Most PSD-95-labeled densities but not all GluR1-labeled clusters were
labeled for N-cadherin. Thus, N-cadherin labeling is associated with
postsynaptic as well as with presynaptic markers and appears to be
concentrated at a population of asymmetric, excitatory synapses some of
which are located on dendritic spines and may represent a distinct
excitatory synapse type or functional state.
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Figure 6.
N-cadherin is associated with excitatory
postsynaptic densities. Confocal images (A-C)
and fluorescence photomicrographs (D, E)
of cultured hippocampal neurons show colocalization of N-cadherin
(D; green) with the excitatory
postsynaptic markers PSD-95 (B, C;
red) and GluR1 (E; red).
A-C, In 29-d-old neurons, in single optical sections,
most N-cadherin puncta cluster at PSD-95-containing postsynaptic
densities, some of which are on dendritic spines. Those indicated by
upper and lower arrowheads in
A-C are shown at higher magnification in the
upper and lower insets,
respectively. D, E, N-cadherin
puncta in 17-d-old neurons also associate with GluR1 clusters.
Boxed regions are shown at higher magnification in
color (red, green, and
overlay) on the right where the
arrowhead illustrates a double-labeled dendritic
spine. Scale bars: A-C, 7.5 µm
(insets, 1.7 µm); D, E,
18 µm, higher magnification, 6 µm.
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To examine whether the absence of N-cadherin from GABAergic pathways
was a general phenomenon in mature brain, we double-immunolabeled sections from mouse, rat, and monkey brain for N-cadherin and GAD and
examined the sections by confocal microscopy. Localization in
hippocampal region CA3 revealed most dramatically the
differential distribution: N-cadherin puncta were restricted to stratum
lucidum, a layer receiving almost exclusively glutamatergic mossy fiber input arising from dentate gyrus granule neurons, whereas GABAergic boutons were concentrated within the adjacent pyramidal cell layer with
little overlap between the two zones (Fig.
7A-C). Similarly, N-cadherin
puncta and GABAergic boutons did not appear to colocalize in any region
examined including cerebral cortex, hippocampus, amygdala, habenula,
dorsal thalamus, thalamic reticular nucleus, caudate-putamen, globus
pallidus, and hypothalamus (Fig. 7A-I). Sections
that were double-immunolabeled for N-cadherin and synaptophysin indicated that the majority of N-cadherin puncta were associated with
synaptophysin (Fig. 7F).
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Figure 7.
GABAergic synapses do not contain N-cadherin, but
they do contain -catenin. A-I, Confocal
images and a bright-field photomicrograph of sections from adult brain
double-labeled for N-cadherin (green) and GAD
(purple) or synaptophysin (red) or
stained for Nissl (D). Sections through the CA3
region of monkey hippocampus (A-C) show
N-cadherin concentrated in mossy fiber terminals in stratum lucidum,
whereas GABAergic terminals are concentrated in the pyramidal cell
layer. Letters on Nissl-stained mouse brain section
D correspond to regions from semiadjacent sections shown
at high magnification in E-I. In single optical
sections through layers II and III of cerebral cortex, GABAergic
synapses (purple) do not contain N-cadherin
(green) (E), but most
N-cadherin puncta (green) are synaptophysin
immunoreactive (red) and appear yellow
(F). Differential distribution of GAD and
N-cadherin is also observed in single optical sections through the
habenula (G), hypothalamus
(H), and caudate-putamen
(I). J-L, Confocal images
taken from 14-d-old cultured rat hippocampal neurons show -catenin
(green) and GAD (purple)
immunolabeling separately (J, K)
and overlaid (L) where regions of colocalization
appear white. Each purple GAD-labeled
bouton associates with green -catenin-labeled
clusters (e.g., arrows). The bouton indicated by the
top arrow is shown at high magnification in the
inset, where the two labels can be seen to colocalize
over a central white area. Scale bars:
A-C, 17 µm; D, 1 mm; E,
F, 7 µm; G-I, 7.5 µm;
J-L, 5.6 µm (insets, 2.8 µm).
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-Catenin is concentrated at GABAergic synapses
-Catenin binding and clustering at cadherin intracellular
domains are common to all classic cadherin-mediated junctions and are,
in fact, required for adhesion (Ozawa et al., 1990; Gumbiner and
McCrea, 1993; Peifer et al., 1993; Oyama et al., 1994; Haegel et al.,
1995; Cox et al., 1996). In cells lacking cadherins, catenins never
form clusters at sites of cell-cell contact (Kemler, 1993; Nakagawa
and Takeichi, 1995). It follows that if cadherins are components of all
synaptic junctional complexes, then GABAergic synaptic sites may
contain -catenin. To examine this, we double-immunolabeled 14-d-old
neurons for GAD and -catenin. Analysis by confocal microscopy showed
that GAD-labeled boutons colocalized with -catenin-labeled clusters, and similar to the localization of N-cadherin and
synaptophysin, -catenin clusters partially overlapped with the
presynaptic GAD label but extended over a greater area to what is
likely to be the postsynaptic surface as well (Fig. 7J-L).
These data suggest that although early GABAergic synaptic junctional
complexes contain N-cadherin, mature and late-forming GABAergic
synaptic junctional complexes do not but are likely to contain another
as yet unidentified cadherin. Thus, cadherins may be required for the
formation or stabilization of both excitatory and inhibitory synaptic
junctional complexes, but different cadherins are highly likely to be
preferentially incorporated into each.
-Catenin in neurons is both synaptic and nuclear
Cadherin-mediated adhesion is accompanied by -catenin
clustering at adhesion sites. To determine whether the synaptic
clustering of cadherins was in fact adhesive as well as to further
examine the potential role of cadherins during synapse assembly, we
compared the immunolocalization of -catenin with that for
N-cadherin and synaptophysin before and during synaptogenesis. In
general, most -catenin labeling was found in puncta that were
smaller and more broadly distributed than N-cadherin puncta and that
frequently were concentrated in larger clusters, similar to what has
been described by Uchida et al. (1996) in mouse brain. It was also found concentrated at sites of soma-soma contact. Interestingly, similar to what has been described within a number of developing as
well as cancerous tissues, -catenin was found within nearly all
neuronal nuclei (Fig.
8A,B).
Nuclear label was distributed throughout the nucleoplasm and was not
observed within nucleoli. These data suggest that in addition to its
actions associated with cadherin-based adhesion at the cell surface,
neuronal -catenin is likely to participate in a cytoplasm-to-nucleus
signaling pathway similar to what has been described in other systems
(Gumbiner, 1997; Shapiro, 1997).
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Figure 8.
-Catenin is found at synapses and in
nuclei. A, B, Projection of confocal
images through an entire cell somata (10 × 1 µm) indicates both
surface -catenin labeling and label within the nucleus
(A), but projection of a subset of the same
images (3 × 1 µm) emphasizes the nuclear distribution
(B). The nucleolus is unlabeled, and the nuclear
envelope appears to be labeled in a punctate manner. C,
D, Fluorescence and phase photomicrographs show
-catenin-labeled puncta in both axons and young dendrites before
synapse formation. Although not concentrated particularly in growth
cones, puncta are observed occasionally in filopodia
(insets). E, F,
-Catenin-labeled puncta (green) colocalize
with synaptophysin-labeled (red) synapses as shown in
phase and fluorescence photomicrographs of 13-d-old cultured
neurons. Boxed regions indicated in E and
F are shown at higher magnification on the
right separately and overlaid.
G-I, In confocal images of 26-d-old neurons,
N-cadherin-labeled puncta (H; red)
represent a subpopulation of -catenin-labeled puncta
(G; green). Most of the large -catenin
puncta correspond to those labeled for N-cadherin
(G-I). Scale bars: A,
B, 6 µm; C, D, 27 µm
(insets, 6 µm); E, F, 20 µm (boxes, 10 µm); G-I, 2 µm.
|
|
The developmental localization of -catenin labeling was similar to
that for N-cadherin in that it was polarized somewhat to axons and
usually found in axonal growth cones, but not concentrated there (Fig.
8C,D). At all stages of synapse formation,
clusters of -catenin puncta corresponded to synapses (Fig.
8E,F), and N-cadherin puncta
were associated with -catenin clusters (Fig. 8G-I). -Catenin puncta were observed at other
sites, but the largest -catenin clusters often corresponded to
N-cadherin sites (Fig. 8I). These data indicate that
cadherins and -catenin are associated with synapses from the time at
which synaptophysin concentrations can first be detected, suggesting
that cadherins are likely to be integral components of all developing
synaptic junctional complexes. Furthermore they support the idea
(Peters et al., 1991; Fannon and Colman, 1996; Uchida et al., 1996)
that cadherin interactions at synapses are similar to those at adherens junctions.
| |
DISCUSSION |
It has been suggested that the differential distribution of
selected cadherins is responsible for linking up and locking in pre-
and postsynaptic membranes of synaptic junctional complexes (Fannon and
Colman, 1996). Findings of the present study support this contention.
In cultured hippocampal neurons, N-cadherin is expressed initially at
all synaptic sites, excitatory and inhibitory, from the time at which
synapses are first detected. However, although N-cadherin is maintained
at glutamatergic synaptic sites as the system matures, it is rapidly
lost from GABAergic synaptic sites. GABAergic synapses appear to
contain another as yet unidentified cadherin, insofar as they all
associate with -catenin, an obligatory binding partner of the
classic cadherins. Together our findings indicate that cadherins may
stabilize the earliest synaptic contacts and, more importantly, that
N-cadherin is the first cell-cell adhesion molecule thus far described
that differentiates between functionally distinct synaptic types
(excitatory and inhibitory) that have different morphologies across
their adhesive face (asymmetric and symmetric). Thus, in addition to
neurotransmitters and receptors, synapses can be distinguished by
distinct sets of scaffolding proteins. These findings suggest that in
hippocampus, N-cadherin adhesion may represent a critical step in
synapse formation, after which a number of cadherins may become
differentially targeted to specific synapse sites and serve to refine
and restrict synaptic connectivity.
Cadherins distinguish functionally distinct synaptic sites
Our results indicate that N-cadherin is concentrated at
excitatory synaptic sites in mature hippocampal neurons in culture and
in vivo and is not associated with inhibitory synaptic sites in a number of brain regions. N-cadherin is also found within cerebellar mossy fiber terminals (Fannon and Colman, 1996) and in
retinotectal projections, (Yamagata et al., 1995; Uchida et al., 1996;
Wöhrn et al., 1998), both of which use glutamate as their
neurotransmitter. Taken together, the data suggest that N-cadherin may be a common component of glutamatergic synapses corresponding to a variety of different pathways. On the other hand,
inhibitory synapses appear to contain a different cadherin (or
cadherins) in that N-cadherin is lost but -catenin is retained at
mature GABAergic synaptic sites in hippocampal neurons. In cerebellum,
-N-catenin, which binds to -catenin, is also clustered at
symmetric (inhibitory) synapses (Uchida et al., 1996). The localization
of catenins to GABAergic sites is significant in that catenins do not
cluster at sites of cell-cell contact in cells lacking cadherins
(Kemler, 1993; Nakagawa and Takeichi, 1995). Although it remains
possible that catenins cluster at GABAergic synapses by their
interactions with a different family of molecules, the most likely
interpretation of our results is that, within individual neurons,
cadherins can be targeted differentially to functionally distinct
synaptic sites. In addition, populations of excitatory synapses may
also be subdivided and grouped in single neurons because in culture
most, but not all, contain N-cadherin. Differentially expressed
cadherins in brain have been hypothesized to serve as a basis for
interconnecting functionally related areas, nuclei, and laminae (Redies
et al., 1992; Arndt and Redies, 1996; Inoue and Sanes, 1997; Suzuki,
1997; Arndt et al., 1998). Our results extend this notion by
suggesting that cadherin interactions may also be differentially
mediated at synapses within single neurons.
Cadherins and synaptic junctions
Several lines of evidence indicate that cadherins and catenins are
localized to synaptic junctional complexes (Serafini, 1997). Localization by electron microscopy suggests that cadherins and catenins can be concentrated within synaptic clefts or clustered in
subsynaptic zones, often at the edges of synaptic junctional complexes
(Yamagata et al., 1995; Fannon and Colman, 1996; Uchida et al., 1996).
Confocal microscopic data indicate that N-cadherin codistributes with
both pre- and postsynaptic elements and often seems to be concentrated
around presynaptic boutons like a cup or ring around a ball (Fannon and
Colman, 1996) (Fig. 3). Biochemical data indicate that N-cadherin is a
major postsynaptic density protein (Beesley et al., 1995). The precise
three-dimensional localization of cadherins with respect to the zone of
synaptic vesicle release remains to be determined conclusively, but
based on the evidence available, it would seem that whether cadherins are evenly distributed across the entire active zone, intercalated as
spot welds, or surrounding the active zone, they could effectively adhere to and stabilize pre- and postsynaptic membranes (e.g., Spacek
and Harris, 1998).
Adhesion between differentially localized cadherins may underlie some
of the characteristic morphological differences observed between
synapses of which asymmetric and symmetric synaptic junctions are among
the best characterized examples (Gray, 1959; Peters et al., 1991;
Peters and Palay, 1996). At asymmetric synapses, the distance between
pre- and postsynaptic membranes is ~30 nm (Peters and Palay, 1996), a
distance that matches the predicted membrane separation for
N-cadherin-based adhesive junctions (Shapiro et al., 1995). At
symmetric synapses, the separation is somewhat smaller (~20 nm)
(Peters and Palay, 1996) but remains well within the range observed at
other cadherin-mediated junctions (Farquhar and Palade, 1963; Overton,
1971; McNutt and Weinstein, 1973; Staehelin, 1974). Cadherins are
relatively similar to one another in size, but the structure and
intermolecular interactions that have been predicted for N- and
E-cadherin are distinct from one another and can serve as a basis for
predicting slightly different intermembrane distances at junctions
mediated by different cadherins (Overduin et al., 1995; Shapiro et al.,
1995; Nadar et al., 1996).
N-cadherin and -catenin cluster at early synaptic sites
For cadherins to bind homophilically across synapses, they must be
placed in opposing membrane surfaces in both pre- and postsynaptic compartments. Consistent with this function, we find N-cadherin and
-catenin distributed diffusely in both pre- and postsynaptic compartments before synapse formation. Approximately coincident with
synaptic vesicle accumulation, both proteins become clustered at
synaptic sites, and the diffuse distribution, particularly of
N-cadherin, is lost (compare Figs. 2, 3). This progressive change in
localization is remarkably similar to the events leading to the
assembly of desmosomes-specialized cadherin junctions. Before
desmosome formation, junctional components are found in cytoplasmic
pools of punctate labeling (Pasdar and Nelson, 1988). After cell-cell
contact and in the absence of new protein synthesis, desmosomes form
and cytoplasmic puncta disappear, suggesting that the cytoplasmic
puncta were a recruitable pool of junctional components (Hennings and
Holbrook, 1983; Pasdar and Nelson, 1988). The similarity between these
two sets of data strongly suggests that before synapse formation,
N-cadherin and -catenin exist as recruitable pools of molecules
that, after contact, can be rapidly assembled into synaptic junctions
and may therefore be involved in some of the initial adhesion events
underlying formation of synaptic junctions (see also Colman, 1997).
However, the present data also indicate that N-cadherin and -catenin
are not concentrated particularly within and are often absent from
axonal growth cones and their filopodia, which are thought to initiate
synaptogenic interactions (Vaughn, 1989; Cooper and Smith, 1992).
Integrins, immunoglobulin superfamily members, and the potentially
adhesive neuroligins/-neurexins or densin 180-type proteins remain
better candidates for initiating contact (Apperson et al., 1996;
Einheber et al., 1996; Irie et al., 1997; Schachner, 1997). A more
likely role for cadherins would be to stabilize appropriate pathfinding
decisions. This interpretation correlates well with the detection
and accumulation of N-cadherin at the onset of synaptogenesis (but not
before) in the developing chick optic tectum (Yamagata et al.,
1995).
N-cadherin is lost from inhibitory synaptic sites
What might account for the shift in cadherin localization observed
at inhibitory synapses between 7 and 14 d in culture? It is
possible that all inhibitory synapses containing N-cadherin are
eliminated selectively, but the number of GABAergic synapses increases
linearly over the same time period (Bähr and Wolff, 1985; Benson
and Cohen, 1996), making this unlikely. Given that at intermediate time
points faint N-cadherin label was detected at some inhibitory synapse
sites, it seems more likely that N-cadherin may be downregulated at
maturing inhibitory synapses and that new inhibitory synaptic complexes
in mature cultures incorporate an alternate cadherin. It remains
possible that -catenin clusters at inhibitory synapses by a
cadherin-independent mechanism (e.g., Senda et al., 1998), but there
have been reported as many as 38 cadherin and cadherin-related
molecules in brain (Ranscht and Dours-Zimmerman, 1991; Suzuki et al.,
1991; Sano et al., 1993; Sugimoto et al., 1996; Shibata et al., 1997),
and we predict that one or several correspond to an "inhibitory
synapse cadherin."
The shift in N-cadherin localization may simply reflect the maturation
of an appropriate targeting mechanism. Although little is known of the
cellular machinery required, a number of studies have demonstrated that
neurotransmitter receptors are differentially distributed within
dendrites (Gazzaley et al., 1997; Rubio and Wenthold, 1997) and are
usually clustered only opposite their corresponding synaptic terminal
(Craig et al., 1994; Baude et al., 1995; Roche and Huganir, 1995).
Interestingly, the restriction of N-cadherin to excitatory synapses is
coincident with the time at which AMPA and GABA-A receptors first
cluster beneath their neurotransmitter-containing terminals (Craig et
al., 1994; Verderio et al., 1994).
Dual role for -catenin in neurons
The present data show that -catenin clusters associate with
synaptophysin-labeled boutons at all stages of synaptogenesis. This
strongly suggests that cadherins are components of all synaptic junctions in hippocampal cultures and that cadherin interactions at
synapses closely resemble cadherin-mediated adhesion at adherens junctions.
Independent of its role in adhesion, -catenin is also a signal
transduction molecule in the Wnt/wingless growth factor
pathway that mediates dorsal-ventral and anterior-posterior axes
formation in developing vertebrates and anterior-posterior patterning
in developing Drosophila (via armadillo, a -catenin
homolog) (Heasman et al., 1994; Peifer, 1995; Sanson et al., 1996;
Fagotto et al., 1997). Wnt signaling appears to be transduced through a
stabilized pool of cytoplasmic -catenin that via its interaction
with LEF/TCF DNA binding proteins can enter the nucleus and
regulate transcription (Funayama et al., 1995; Gumbiner, 1995; Huber et
al., 1996; Miller and Moon, 1997). In differentiated cells, cytoplasmic
-catenin seems to be tightly controlled in that rising levels and
the resulting activation of Wnt pathway elements can lead to malignant
transformation of some cells (Rubinfeld et al., 1997). Taken in this
context, we found it surprising that -catenin was readily detected
within the nuclei of neurons that have terminally differentiated.
These data suggest that in addition to events leading to cell division, Wnt-like signaling pathways may also be invoked during cell
differentiation (see also Pollack et al., 1997).
Adhesion and synapses
Recent data strongly link changes in adhesion with alterations in
the functional properties of synapses (Lüthi et al., 1994; Rønn
et al., 1995; Muller et al., 1996; Bahr et al., 1977; Grotwiel et al.,
1998; Staubli et al., 1998). In particular, Schuman and colleagues have
demonstrated that disruptions of cadherin-based adhesion attenuated
induction of long-term potentiation (Tang et al., 1998). Given
our findings that suggest cadherins systematically differentiate
between functionally distinct synaptic sites, cadherins together with
catenins may be able to regulate aspects of synaptic junction adhesion
and perhaps even synaptically driven changes in neuron morphology
(e.g., Desmond and Levy, 1986; Geinisman et al., 1994).
| |
FOOTNOTES |
Received April 23, 1998; revised June 15, 1998; accepted June 23, 1998.
This research was supported by National Science Foundation Grant
IBN-9419900 and National Institutes of Health Grant AG15204-01 to
D.L.B. H.T. was supported by 5 P01 NS33165 from the National Institutes of Health. We thank Melba Nagy and Sophie Kay for excellent technical assistance, Drs. Karen Knudsen and David Colman for their
gifts of antibodies, and Drs. George Huntley, David Colman, Javier
DeFelipe, and Adam Gazzaley for valuable discussions and comments on
this manuscript.
Correspondence should be addressed to Dr. Deanna L. Benson, Fishberg
Research Center for Neurobiology, Box 1065, Mount Sinai School of
Medicine, 1425 Madison Avenue, New York, NY 10029.
| |
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Top
Abstract
Introduction
