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The Journal of Neuroscience, March 15, 2002, 22(6):2153-2164
Rapid Synaptic Remodeling by Protein Kinase C: Reciprocal
Translocation of NMDA Receptors and Calcium/Calmodulin-Dependent Kinase
II
Dan K.
Fong,
Anuradha
Rao,
F. Thomas
Crump, and
Ann Marie
Craig
Department of Anatomy and Neurobiology, Washington University
School of Medicine, St. Louis, Missouri 63110
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ABSTRACT |
In contrast to the rapid regulation of AMPA receptors, previous
evidence has supported the idea that the synaptic density of NMDA-type
glutamate receptors is fairly static, modulated only over a long time
scale in a homeostatic manner. We report here that selective activation
of protein kinase C (PKC) with phorbol esters induces a
rapid dispersal of NMDA receptors from synaptic to extrasynaptic plasma
membrane in cultured rat hippocampal neurons. PKC activation induced a
simultaneous translocation of calcium/calmodulin-dependent kinase II
(CaMKII) to synapses but no change in spine number, presynaptic
terminal number, or the distribution of AMPA receptors or the synaptic
scaffolding protein PSD-95. PKC-induced accumulation of CaMKII was
dependent on filamentous actin, whereas dispersal of NMDA receptors
occurred by a different mechanism independent of actin or CaMKII.
Consistent with the decrease in synaptic density of NMDA receptors,
phorbol ester pretreatment reduced excitotoxicity. These results reveal
a surprisingly dynamic nature to the molecular composition and
functional properties of glutamatergic postsynaptic specializations.
Key words:
postsynaptic density; NMDA receptors; calcium/calmodulin-dependent kinase II; protein kinase C; synaptogenesis; synaptic plasticity; hippocampal neurons
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INTRODUCTION |
Glutamatergic synapses are
modifiable cell-to-cell junctions that mediate excitatory synaptic
transmission in the mammalian brain. Underlying the glutamatergic
postsynaptic membrane is a specialized, detergent-insoluble
postsynaptic density (PSD). The NMDA ionotropic glutamate receptor
(NMDAR) and calcium/calmodulin-dependent kinase II (CaMKII) are two
major signaling components of the PSD and have been intensely studied
for their roles in synaptic plasticity (Kennedy, 2000 ). Other major
components of the PSD are structural scaffolds, typified by the PDZ
domain protein PSD-95. PSD-95/SAP90 and related family members link
NMDA receptors with a network of other PSD proteins, including nitric
oxide synthase, the synaptic ras GTPase-activating protein SynGAP, the
cell-adhesion molecule neuroligin, and GKAP scaffolding proteins (Sheng
and Pak, 2000).
NMDA receptors are hetero-oligomers, consisting of the essential NR1
subunit and combinations of NR2A-NR2D and NR3 (Mori and Mishina,
1995). NMDA receptors function as molecular coincidence detectors,
requiring both glutamate binding and depolarization-mediated removal of
Mg2+ block to allow channel opening. The
level of NMDAR function at the synapse critically regulates brain
function. For example, mice expressing 5% of normal levels of NR1
exhibit increased motor activity and deficits in social interactions
(Mohn et al., 1999). At the cellular level, the magnitude and kinetics
of calcium entry through NMDA receptors is thought to be a major
determinant of long-lasting potentiation or depression of synaptic
efficacy in response to a given stimulus (Abraham and Bear, 1996).
These long-term effects are mediated by calcium activation of CaMKII
and protein kinase C (PKC) and other signaling pathways in the
postsynaptic domain.
CaMKII is a holoenzyme composed of ~12 monomers, primarily  and
 subunits in neurons (Soderling et al., 2001). Autophosphorylation of CaMKII at Thr286 is required for normal spatial memory and place-cell representation, presumably through triggering of its calcium-independent kinase activity (Giese et al., 1998). CaMKII phosphorylates several key postsynaptic targets, including the NMDA
receptor subunit NR2B, the AMPA receptor (AMPAR) subunit GluR1, and
SynGAP (Kennedy, 2000; Soderling et al., 2001).
Rapid synaptic modification through regulation of the functional
properties of ion channels and signal-transducing enzymes is a well
established mode of plasticity. More recently, it has been appreciated
that another mode of expression of synaptic plasticity is regulation of
subcellular distribution of ion channels and kinases. Many studies
support the idea that activity rapidly regulates the insertion and
endocytosis of AMPA receptors at synapses (Ehlers, 2000). Translocation
of exogenous CaMKII to synapses has also been visualized in response to
glutamate stimulation (Shen and Meyer, 1999). In contrast, the synaptic
localization of NMDA receptors is thought to be more static. Over a
time course of several days, activity modulates the synaptic levels of
NMDA receptors in a homeostatic direction (Rao and Craig, 1997).
cAMP-dependent protein kinase mediates this long-term modulation of
NMDA receptor targeting to synapses (Crump et al., 2001). In exploring
the effects of other kinases, we found that NMDA receptor trafficking
can be dynamically regulated on a time scale of minutes. Selective
activation of PKC induces rapid dispersal of NMDA receptors from
postsynaptic sites to the extrasynaptic plasma membrane. Furthermore,
PKC activation induces a reciprocal translocation of CaMKII to
postsynaptic sites but has no effect on the distribution of PSD-95.
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MATERIALS AND METHODS |
Cell culture. Rat hippocampal cultures were prepared
from 18-d-old rat embryos by previously described methods (Goslin et al., 1998). Briefly, hippocampi were dissected and dissociated using
trypsin and trituration through a Pasteur pipette. The neurons were
plated on coverslips coated with poly-L-lysine in
MEM with 10% horse serum and allowed to attach for 3-4 hr. After
attachment, the neurons were transferred to a dish containing a glial
monolayer and maintained for up to 4 weeks in serum-free MEM with N2
supplements. Standard cultures were plated at the low density of
2400-4800 cells/cm2. High-density
cultures were plated at 14,300 cells/cm2.
Neurons were chronically treated with 100 µM
APV or 10 µM MK-801 beginning on day 7, with
renewal every 3-4 d (except for the  APV experiments described in
Figs. 1 and 8). All analyses were
performed at 18-28 d. Pharmacological agents were used at the
following concentrations: 100 nM
12-O-tetradecanoylphorbol-13-acetate (TPA) (Sigma, St.
Louis, MO), 100 nM 4-TPA (Sigma), 10 µM phorbol 12,13-diacetate (PDA) (Sigma), 100 nM phorbol didecanoate (PDD) (Sigma), 100 nM 4-PDD (Sigma), 10-200
nM bisindolylmaleimide (LC Laboratories, Woburn,
MA), 100 µM APV (Research Biochemicals, Natick,
MA), 10 µM MK801 (Research Biochemicals), 2.5 µM NMDA (Alexis, San Diego, CA), 2 µM jasplakinolide (Molecular Probes, Eugene,
OR), 5 µM latrunculin A (Biomol Research
Laboratories, Plymouth Meeting, PA), 10 µM KN62 (Alexis),
3-30 µM KN93 (Calbiochem, La Jolla, CA), 10 µM lavendustin A (Calbiochem), 10 µM CNQX (Sigma), 50 µM
picrotoxin (Sigma), 200 µM AP-3 (Alexis), 5 µM nifedipine, and 1 µM
TTX (Sigma). With the exception of chronic APV/MK801 and latrunculin A
treatment, pharmacological agents were added to the culture media for
45-120 min before the addition of TPA.
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Figure 1.
PKC-induced synaptic remodeling: dispersal of NMDA
receptors and synaptic translocation of CaMKII. Hippocampal neurons
were cultured for 3 weeks at high density (APV, a-d)
or at low density in the presence of APV (e-h). Sister
neurons were left untreated [controls (Con), a,
c, e, g] or treated for 45 min with TPA (b, d, f,
h), fixed, and immunolabeled for NR1
(green, a, b, e, f) or
CaMKII (green, c, d, g, h) and
synapsin (Syn; red). Areas of overlap
between the presynaptic vesicle antigens and postsynaptic NR1 or
CaMKII appear yellow. a, e, In
high-density or APV-treated low-density control neurons, NR1 is found
predominantly in synaptic clusters. b, f, TPA treatment
resulted in dispersal of NR1 away from synapses to a diffuse dendritic
shaft distribution. c, g, In high-density or APV-treated
low-density control neurons, CaMKII is concentrated at some synapses
but is also present at high levels throughout dendrites and axons.
d, h, TPA treatment resulted in enhanced clustering of
CaMKII at synapses and reduced levels in dendrite shafts.
PKC-induced NR1 dispersal and CaMKII synaptic translocation occurred
under conditions of spontaneous activity (a-d) and
under conditions of NMDA receptor blockade (e-h).
Boxed regions in e-h are shown below at
higher magnification. Scale bars, 10 µm.
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Immunocytochemistry. Immunolabeling was performed
essentially as described previously (Rao and Craig, 1997; Allison et
al., 2000). Briefly, for NR1, NR2A, NR2B, CaMKII, and PSD-95,
neurons were fixed in methanol for 10 min at 20°C, blocked with
10% BSA for 30 min, and incubated overnight at room temperature with
primary antibodies diluted in 3% BSA/PBS. For AMPA receptor and
filamentous actin (F-actin) labeling, neurons were fixed in warm 4%
paraformaldehyde/4% sucrose in PBS for 15 min at room temperature and
permeabilized with 0.25% Triton X-100 for 5 min. The following mouse
monoclonal antibodies were used: NR1 (clone 54.1; PharMingen, San
Diego, CA; 1:1500), CaMKII (clone 6G9; Affinity Bioreagents, Golden, CO; 1:200), and PSD-95 (clone 6G6-1C9; Affinity Bioreagents; 1:2000; interacts with other members of the PSD/SAP family). For double labeling of NR1 and PSD-95 or NR2A, mouse NR1 (clone 54.1; PharMingen) and 1 µg/ml guinea pig anti-PSD-95 antiserum (gift from M. Sheng, Massachusetts Institute of Technology, Cambridge, MA) or 1 µg/ml rabbit anti-NR2A antiserum (gift from M. Sheng) were used. Other rabbit
antibodies used were anti-NR2B (Upstate Biotechnology, Lake Placid, NY;
4.2 µg/ml), anti-GluR1 (gift from R. McIlhinney, Oxford University,
Oxford, UK; 1:2000), and anti-MAP2 (gift from S. Halpain, Scripps
Research Institute, La Jolla, CA; 1:10,000). F-actin was labeled using
Texas Red-conjugated phalloidin (Molecular Probes; 1:200). Presynaptic
terminals were revealed with rabbit antibodies to synaptophysin (G95;
gift from P. DeCamilli, Yale University, New Haven, CT; 1:8000) or
synapsin (Chemicon, Temecula, CA; 1:5000) or with mouse anti-SV2
(Developmental Studies Hybridoma Bank, Iowa City, IA; 1:40).
Appropriate secondary antibodies conjugated to Texas Red, FITC, or
biotin (Jackson ImmunoResearch, West Grove, PA, or Vector Laboratories,
Burlingame, CA; 2.5-7.5 µg/ml) were added and incubated for 45 min
at 37°C, followed by extensive washes with PBS. In cases in which
biotin-conjugated secondary antibodies were used, either FITC or Texas
Red/streptavidin (Jackson ImmunoResearch; 1:2000) was used as a
tertiary reagent. Coverslips were mounted in elvanol (Tris-HCl,
glycerol, polyvinyl alcohol with 2%
1,4-diazabicyclo[2,2,2]octane).
DiI labeling. The lipophilic dye DiI (Molecular Probes) was
used to label the plasma membrane outline of random subsets of neurons
(Hasbani et al., 2001). Neurons were fixed for 30 min in warm 4%
paraformaldehyde/4% sucrose in PBS, washed in PBS, incubated in a
freshly made suspension of DiI (0.4 µg/ml in PBS) for 30 sec, and
washed further in PBS. Neurons were mounted and imaged immediately.
Microscopy and immunofluorescence quantification.
Fluorescent and phase-contrast images of neurons were obtained on a
PhotoMetrics (Roper Scientific, Tucson, AZ) Sensys cooled CCD camera
mounted on a Zeiss (Thornwood, NY) Axioskop microscope with a 63×, 1.4 numerical aperture lens using Oncor or Metamorph (Universal Imaging, West Chester, PA) software. Before quantification, CCD images were
processed by dark-field subtraction and correction for any nonuniformity in illumination. To define synaptic NR1, CaMKII, or
PSD-95 clusters, thresholds for individual neurons and channels were
chosen manually and corresponded to two times the average intensity of
fluorescence in the dendritic shaft. Binary images of clusters of each
postsynaptic marker (NR1, CaMKII, or PSD-95) were compared with binary
images of synapsin or synaptophysin clusters. Any postsynaptic cluster
that had at least one pixel of overlap with a presynaptic cluster was
defined as synaptic. Data analysis was performed using Metamorph,
Microsoft (Seattle, WA) Excel, Statview, and Delta Graph (Chicago, IL).
Values indicate mean ± SEM. Group comparisons were made by
t test. Images were processed and prepared for print using
Adobe Photoshop (Adobe Systems, San Jose, CA).
Chymotrypsin treatment and Western blot analysis. Neurons
were subjected to chymotrypsin protease treatment before harvesting and
Western blot analysis to determine surface NR1 expression (Hall and
Soderling, 1997). Briefly, 3 week, high-density (14,300 cells/cm2) dishes of cultured neurons were
washed twice with warm HEPES-buffered saline solution, incubated in 1 mg/ml chymotrypsin in saline solution for 10 min, and then washed three
times in saline solution containing 2 mM PMSF to
inactivate chymotrypsin. Neurons were scraped into warm PBS, pelleted,
and resuspended in Laemmli buffer. Samples were pooled from 15 to 20 coverslips per condition, and small aliquots were analyzed by SDS-PAGE
to estimate total protein concentration. Equal amounts of protein
between conditions were run on SDS-PAGE, transferred to a
nitrocellulose membrane, blocked with 5% nonfat dried milk for 1 hr,
and incubated overnight at 4°C with anti-NR1 antibody (clone 54.1;
mouse anti-NR1; 1:4000). Blots were washed with TBS, incubated for 1 hr
in HRP-conjugated secondary goat anti-mouse antiserum (Jackson
ImmunoResearch; 1:5000), and visualized using chemiluminescent
Super-Signal HRP substrate (Pierce, Rockford, IL) and exposure to x-ray
film. As a control for protein loading between conditions, the blots
were reprobed with rabbit anti-tau (Sigma; 1:10,000). The film signals
were digitally scanned and analyzed using Metamorph or NIH Image
densitometric analysis.
Triton X-100 extraction. Live neurons were
detergent-extracted (Allison et al., 2000) with 1% Triton X-100 and
4% 40,000 kDa polyethylene glycol in BRB80 (80 mM PIPES, 1 mM
MgCl2, 1 mM EDTA) for 5 min, rinsed twice with BRB80, fixed in methanol, and stained for rabbit
anti-MAP2 and mouse anti-NR1 or mouse anti-CaMKII.
Excitotoxicity. For the toxicity assay (Crump et al., 2001),
neurons were removed from APV and TPA pretreatments, placed in high-K+ buffer (in
mM: 90 KCl, 31.5 NaCl, 2 CaCl2, 25 HEPES, 1 glycine, 30 glucose) for 3 min
to induce the synaptic release of glutamate, and incubated for an
additional 60 min in normal medium. Neurons were then incubated in
0.4% Trypan blue for 5 min and counted using the exclusion of dye as
an indicator of cell viability. Approximately 150-200 neurons were
scored per coverslip, and at least eight coverslips per group were
scored from at least four independent cultures. Sister coverslips used
for excitotoxicity analysis were fixed and immunostained to confirm the
differential localization of NR1 with APV and TPA pretreatments.
NR1-green fluorescent protein expression and live imaging.
The NR1-green fluorescent protein (GFP) and NR2A expression plasmids have been described previously (Crump et al., 2001). Neurons were transfected either at plating or 7-10 d after plating with
GW1-NR1C-GFP and GW1-NR2A using Effectene reagent (Qiagen, Hilden,
Germany) essentially according to the manufacturer's instructions. Low amounts of expression plasmid were used (0.1-0.5 µg per 60 mm dish)
resulting in fairly dim but appropriately localized NR1-GFP. For
colabeling of CaMKII, neurons were grown to day 21-28, fixed, and
stained with mouse anti-CaMKII and donkey Texas Red anti-mouse antibodies. For live visualization of NR1-GFP, neurons were plated on
poly-L-lysine-coated coverslips attached via
silicone to a hole in the bottom of a tissue culture dish. Glia were
grown on coverslips and suspended above the neurons by paraffin wax
dots. The neurons were transfected at plating and grown in phenol
red-free MEM with N2 supplements for 18-24 d.
Imaging was performed after addition of the anti-oxidants
N-acetyl-cysteine (60 µM) and trolox (20 µM) to the medium. Imaging was performed on
a Nikon (Tokyo, Japan) TE200 with a Prior XYZ stage, Sutter excitation
and emission filter wheels (Sutter Instruments, Novato, CA), a
transmitted light shutter, a Princeton Micromax 1300 YHS-cooled CCD
camera (Roper Scientific), and Metamorph software. NR1-GFP-expressing cells were located, and images were acquired rapidly to prevent changes
in the pH of the medium. TPA was added, neurons were returned to the
37°C CO2 incubator for 30 min, and the same
cells were relocated and imaged again. Quantification of fluorescent
intensity was performed in Metamorph. Spines did not exactly align
between time points because of spine motility, so the pixel area for
measuring spine fluorescence was manually centered over each spine for
each image.
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RESULTS |
Synaptic remodeling by PKC: NMDA receptors and CaMKII
Effects of kinase activation on synaptic composition were assessed
by immunocytochemistry in cultured neurons. Primary embryonic rat
hippocampal neurons were grown under conditions in which NMDA receptors
cluster at synapses, either at high density in the absence of
pharmacological agents or at low density in the presence of NMDA
receptor antagonists (Rao and Craig, 1997; Crump et al., 2001). To
examine the role of PKC activity in the synaptic localization of NMDA
receptors, pyramidal cells were treated with 100 nM TPA (a
PKC agonist) for 45 min, fixed, and double labeled with antibodies to
the essential NMDAR subunit NR1 and to synapsin or synaptophysin as
markers for presynaptic terminals. In high-density neurons cultured for
16-18 d, NR1 was intensely clustered and highly apposed to presynaptic
terminals (Fig. 1a). After TPA treatment for 45 min, NR1
dispersed away from the postsynaptic compartment and was no longer
clustered (Fig. 1b). In the TPA-treated neurons, NR1
immunoreactivity appeared similar to that of uniformly distributed proteins in the dendritic plasma membrane. TPA treatment had no effect
on the distribution of synaptic vesicle antigens as assessed by light
microscopy. Puncta corresponding to presynaptic terminals were numerous
in the control and TPA-treated cultures. Another phorbol ester that
activates PKC, PDD, induced a similar dispersal of NR1, whereas
4-TPA and 4-PDD, which do not activate PKC, had no effect on
NMDAR distribution (data not shown).
In contrast to the PKC-mediated dispersal of NMDA receptors, TPA had
the opposite effect on localization of another major PSD protein,
CaMKII. In control neurons, CaMKII immunoreactivity is
concentrated in some spines but also present throughout dendritic shafts (Fig. 1c). Activation of PKC with TPA induced a
dramatic translocation of CaMKII from the dendritic shaft to spine
synapses (Fig. 1d). The translocation of CaMKII to
synapses was specifically induced by active phorbol esters and not the
inactive analog (data not shown). Thus, activation of PKC induces
opposing effects on two major synaptic components, dispersal of NMDA
receptors away from synapses and translocation of CaMKII to synapses.
To determine whether NMDA receptor activity was required for the
TPA-induced dispersal of NMDA receptors or synaptic translocation of
CaMKII, TPA treatment was performed in the presence of the NMDA
receptor antagonist APV. For these experiments and most of the
subsequent experiments, we used 3 week low-density neurons chronically
pretreated with APV, which show strong synaptic clustering of NMDAR
(Fig. 1e) and a partially spiny localization of CaMKII (Fig. 1g), similar to the high-density untreated cultures.
Activation of PKC with TPA resulted in dispersal of NR1 and enhanced
synaptic clustering of CaMKII even in the presence of NMDA receptor
antagonist (Fig. 1f,h). Thus, NMDAR activity was not
required and had no apparent effect on PKC-induced dispersal of NMDAR
or clustering of CaMKII.
Quantitative immunofluorescence analysis was performed on randomly
chosen populations of neurons immunolabeled for NR1 or CaMKII and
synaptic vesicle antigens. Compared with control neurons, TPA treatment
resulted in a significant decrease in synaptic NR1 (50.1 ± 1.8 synaptic NR1 clusters/100 µm dendrite in controls vs 9.8 ± 0.9 synaptic NR1 clusters/100 µm dendrite in TPA-treated neurons;
t test; p < 0.01; n  85 neurons per group from seven independent cultures) and a significant
increase in synaptic CaMKII (7.2 ± 0.6 synaptic CaMKII
clusters/100 µm dendrite in controls vs 26.4 ± 1.1 synaptic
CaMKII clusters/100 µm dendrite in TPA-treated neurons;
t test; p < 0.01; n 79 neurons per group from seven cultures). These effects of TPA were
blocked by coincubation with bisindolylmaleimide, a specific inhibitor
of PKC (43.8 ± 3.8 synaptic NR1 clusters/100 µm dendrite and
9.4 ± 1.5 synaptic CaMKII clusters/100 µm dendrite in
TPA/bisindolylmaleimide-treated neurons; p < 0.01 compared with TPA-treated neurons; p > 0.1 compared
with control neurons; n 22 neurons per group from
two cultures). Thus, the effects of TPA on redistribution of NMDAR and
CaMKII are mediated by activation of PKC. PKC activation had no effect
on the density of presynaptic inputs, quantified as puncta of
synaptophysin or synapsin per dendrite length (82.2 ± 2.2 terminals/100 µm dendrite in controls vs 82.4 ± 2.3 terminals/100 µm dendrite in TPA-treated neurons; p > 0.1; n 136 neurons per group from eight cultures).
PKC effects on PSD-95, AMPA receptors, and spines
The effect of PKC activation on the localization of other
prominent postsynaptic components was examined. Neurons were treated with TPA, fixed, and stained with combinations of antibodies to synapsin or synaptophysin, the NMDA receptor subunits NR1, NR2A, and
NR2B, the AMPA receptor subunit GluR1, and the PDZ domain postsynaptic
scaffolding protein PSD-95. As expected, the NR2A and NR2B subunits of
the NMDA receptor dispersed away from synapses in concert with the NR1
subunit and appeared to be diffuse and membrane associated (Fig.
2a,a',b,b'; data not shown for
NR2B). Although it binds NR2A and NR2B and colocalizes with NMDAR at synapses in control neurons, PSD-95 did not disperse after activation of PKC (Fig. 2c,c',d,d'). In TPA-treated cells double
labeled for NR1 and PSD-95, NMDAR was diffusely localized along
dendrites, whereas PSD-95 remained punctate and closely apposed to
presynaptic terminals. Quantification revealed no change in the density
of synaptic PSD-95 clusters after PKC activation (67.1 ± 4.9 synaptic PSD-95 clusters/100 µm dendrite in controls vs 63.5 ± 3.3 synaptic PSD-95 clusters/100 µm dendrite in TPA-treated neurons;
p > 0.1; n = 22 neurons per group from
two cultures). The AMPA receptor subunit GluR1 also showed no obvious
change in distribution after activation of PKC (Fig.
2e,e',f,f'). GluR1 was concentrated in some dendrite spines
and detected at lower levels in dendrite shafts in both control and
TPA-treated neurons. The lack of effect of PKC on GluR1 localization is
in agreement with the results of Chung et al. (2000), who found no
change in the density of synaptic GluR2 clusters after TPA treatment.
Thus, PKC activation results in a dramatic selective dispersal of NMDA
receptors and not AMPA receptors or PSD-95.
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Figure 2.
PKC-induced synaptic remodeling: effect on
multiple NMDA receptor subunits and F-actin but not on AMPA receptor,
PSD-95, or spine density. a, a', c, c', In control
(Con) neurons, NR1 coclusters with NR2A and PSD-95.
b, b', d, d', After 30 min of TPA treatment, PSD-95
remained clustered at synapses, whereas NR2A dispersed away from
synapses along with NR1. e, e', f, f', There was no
apparent change in the synaptic localization of GluR1 between control
and TPA-treated neurons. g, h, TPA treatment increased
the concentration of F-actin in dendritic spines and reduced
filamentous actin in dendrite shafts, mirroring the rearrangement of
CaMKII. i, j, TPA treatment had no effect on the
overall number of spines but may alter their size and shape. Scale bar,
10 µm.
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To assess the effects of PKC activation on more general features of
spine structure and density, control and TPA-treated neurons were fixed
and stained with Texas Red phalloidin to reveal filamentous actin or
labeled with a suspension of DiI to reveal dendritic membrane profiles.
As reported previously (Allison et al., 1998), F-actin appeared to be
highly concentrated in dendritic spines in control neurons (Fig.
2g). F-actin appeared to accumulate further in spines after
PKC stimulation (Fig. 2h), however, and there appeared to be
a slight rounding of spine heads in TPA-treated cells (Fig.
2i,j). Despite the dynamic remodeling of postsynaptic components, the number of dendrite spines was not affected by PKC
activation. Spine density quantified from dendrites randomly labeled
with DiI was not significantly different between control and
TPA-treated neurons (49.8 ± 3.8 protrusions/100 µm dendrite for
controls vs 44.9 ± 3.4 protrusions/100 µm dendrite for
TPA-treated cells; p > 0.1; n 19 neurons per group from four cultures).
Rapid time course and reversal of synaptic remodeling by PKC
Given the striking molecular rearrangement of NR1 and CaMKII in
opposite directions within the postsynaptic compartment, we asked
whether movement of these two PSD core components occurred on the same
time course and thus might be related (Fig.
3a,b). Even 5 min of TPA
treatment resulted in a partial dispersal of NR1 and clustering of
CaMKII. The redistributions of both NR1 and CaMKII were
approximately half-maximal within 10 min and maximal by 45 min of TPA
treatment. These results reveal unexpectedly rapid dynamics in the
molecular organization of the hippocampal postsynaptic compartment.
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Figure 3.
Rapid time course and reversal of synaptic
remodeling. a, b, Neurons were exposed to TPA for the
indicated times, fixed, and immunolabeled for NR1
(a) or CaMKII (b) and
synapsin (Syn). An initial observable effect on NR1 and
CaMKII localization was seen as early as 5 min after addition of
TPA. At 10 min, the effect of TPA on NR1 and CaMKII translocation
was approximately half-maximal, and at 45 min the effect was complete.
c, The effect of PDA on the distributions of NR1 and
CaMKII was similar to that of TPA. A 1 hr washout of PDA resulted in
significant reversal; NR1 again became more localized to synapses and
CaMKII more diffuse. Reversal also occurred after an 8 hr washout in
the presence of the protein synthesis inhibitor cycloheximide. Scale
bar, 10 µm.
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Furthermore, these effects of PKC activation on synaptic remodeling
were rapidly reversible. The effect of a 1 hr treatment with PDA (a
relatively water-soluble activator of PKC) in dispersing NMDA receptors
and clustering CaMKII was similar to that of treatment with TPA (Fig.
3c). After only 1 hr of washout of the PDA, NR1 and CaMKII
showed a significant reversal in distribution; NR1 returned to the
highly synaptic pattern and CaMKII to the partially spiny pattern. An 8 hr reversal in the presence of the protein synthesis inhibitor
cycloheximide also showed reaccumulation of NR1 at synapses. Thus, the
reappearance of synaptic NR1 suggests that the translocation of
previously dispersed NMDA receptor contributed to the synaptic pool of
NMDA receptors.
Mechanisms of PKC-induced synaptic remodeling
Possible mediators of the PKC-induced redistribution of NMDA
receptors and CaMKII include actin reorganization, other kinases, and
synaptic activity; therefore, we tested these possibilities pharmacologically. NMDA receptors and CaMKII hetero-oligomers have
close associations to the F-actin cytoskeleton (Wyszynski et al., 1997;
Shen et al., 1998), and we observed a PKC-induced increase in synaptic
F-actin (Fig. 2g,h). We used jasplakinolide, a
cell-permeable molecule that binds to and stabilizes F-actin (Halpain
et al., 1998), to prevent rearrangements in the actin cytoskeleton. We
tested whether CaMKII activity is necessary for PKC-induced NMDAR
dispersal or for its own translocation by treatment of cultured
hippocampal neurons with the CaMKII inhibitor KN62 before and during
the addition of TPA. Another kinase that has been implicated in NMDA
receptor modulation and has associations with the NMDA receptor complex
is Src. Activation of PKC by phorbol esters results in the tyrosine
phosphorylation of NR2A/B (Grosshans and Browning, 2001), and Src
mediated NMDA receptor modulation has been shown to be downstream of
PKC activation (Lu et al., 1999). Therefore, we examined the
participation of Src in postsynaptic remodeling by treating hippocampal
neurons with the tyrosine kinase inhibitor lavendustin A before and
during TPA treatment. We found no significant difference between
neurons treated with TPA alone, jasplakinolide/TPA, KN62/TPA, or
lavendustin A/TPA with respect to the number of synaptic clusters of
NR1 or CaMKII (Fig. 4). The role of
CaMKII activity was tested further using a separate inhibitor, KN93
(3-30 µM range), which again did not block the PKC-induced redistribution (26.6 ± 1.8 synaptic clusters of
CaMKII per 100 µm dendrite in neurons treated with TPA/KN93 at 30 µM; p > 0.1 compared with
TPA-treated neurons). Thus, PKC-induced NMDA receptor dispersal and
CaMKII translocation occur independently of F-actin dynamics, CaMKII
activity, and tyrosine kinase activity.
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Figure 4.
Mechanisms of NMDAR and CaMKII synaptic remodeling
by PKC: independence from actin reorganization, CaMKII, tyrosine
kinase, and synaptic activity. TPA decreased the number of synaptic NR1
clusters per dendritic length and increased the number of synaptic
CaMKII clusters per dendrite length compared with control neurons
(n 79 neurons from 7 separate cultures;
p < 0.01). Cotreatment with bisindolylmaleimide
(Bis), a specific inhibitor of PKC, blocked these
effects of TPA (n 22 neurons from 2 cultures;
p < 0.01 compared with TPA; p > 0.1 compared with control). Cotreatment with jasplakinolide
(Jasplak), KN62, lavendustin A (Lav A),
or blockade (a combination of TTX, nifedipine, picrotoxin, CNQX, APV,
and AP-3) did not significantly alter the degree of NR1 dispersal or
CaMKII synaptic translocation induced by TPA (n 19 from at least 2 cultures; p > 0.09).
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In addition to direct postsynaptic effects, phorbol esters enhance
presynaptic vesicle fusion (Malenka et al., 1986; Parfitt and Madison,
1993). We thus determined whether the synaptic remodeling of NMDAR and
CaMKII was attributable to postsynaptic PKC activity rather than
presynaptic vesicle release. Pharmacological presynaptic and
postsynaptic blockade was mediated by a cocktail of
inhibitors to voltage-gated sodium channels (tetrodotoxin),
voltage-gated L-type calcium channels (nifedipine), inhibitory GABA
receptors (picrotoxin), and glutamate receptors of the AMPA, NMDA, and
group I metabotropic glutamate receptors subtypes (CNQX, APV, and
AP-3). We again found no significant effect of these agents on
TPA-induced dispersal of NMDAR or clustering of CaMKII (Fig. 4),
suggesting a direct postsynaptic effect of PKC.
PKC modulation of postsynaptic density and
cytoskeletal associations
We used detergent extraction after TPA treatment to determine the
strength of associations of NR1 and CaMKII to the cytoskeleton. Insolubility of postsynaptic density components in the detergent Triton
X-100 supports the tight associations of NR1, NR2, CaMKII/, and
PSD-95 among themselves and/or the cytoskeleton (Kennedy, 2000).
Detergent extraction has classically been used for isolation of
postsynaptic densities from biochemical synaptosome fractions (Kennedy,
2000) and can also be used to assess molecular interactions at the PSD
in cultured hippocampal neurons (Allison et al., 1998). Treatment of
living neurons with Triton X-100 had little effect on the distribution
of NMDAR in control neurons; most of the NR1 was associated with the
postsynaptic site and remained associated with the PSD after extraction
(Fig. 5a,b) (Allison et al.,
1998). After TPA treatment, however, much of the NR1 had dispersed out of the PSD region and was now extracted, whereas the small amount of
NR1 remaining within the PSD region was unextracted (Fig.
5c,d). Conversely, in control neurons, much of the cellular
CaMKII was extrasynaptic and was extracted by Triton X-100, leaving
only small amounts at the postsynaptic site (Fig.
5e,f) (Allison et al., 2000). After TPA treatment,
much of the cellular CaMKII had translocated to the PSD region and
now became resistant to Triton-100 extraction (Fig. 5g,h).
Thus, PKC-induced dispersal of NMDAR involves breakage of
Triton-resistant associations, whereas PKC-induced clustering of CaMKII
involves formation of new Triton-resistant associations with
postsynaptic density components.
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Figure 5.
PKC-induced change in cytoskeletal association of
NMDAR and CaMKII. Neurons were fixed immediately after a 45 min
treatment with TPA (+TPA) and/or after subsequent
extraction of living neurons with Triton X-100
(+EXT). Neurons were immunolabeled for NR1 or
CaMKII (green) and the dendritic
microtubule-associated protein MAP2 (red). a,
b, In control neurons, NR1 was primarily punctate and spiny and
was not extracted by detergent. c, d, In TPA-treated
neurons, most of the diffusely localized NR1 was extracted by
detergent, leaving only small amounts in dendritic spines. e,
f, In control neurons, most of the diffusely localized
CaMKII was extracted by detergent, leaving only small amounts in
dendritic spines. g, h, In TPA-treated neurons,
CaMKII was largely punctate and spiny and was not extracted by
detergent. MAP2 localization and cytoskeletal association were not
affected by TPA treatment. Boxed regions in
a-h are shown below at higher
magnification. Scale bar, 10 µm.
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To further understand the nature of these molecular associations, we
determined the effect of depolymerization of F-actin on the
distributions of NR1 and CaMKII and their redistribution by PKC (Fig.
6). As reported previously (Allison et
al., 1998, 2000), a 9 hr treatment with latrunculin A induced a loss of
spine F-actin, a complete dispersal of CaMKII, and a modest conversion of NMDA receptors from spiny to nonsynaptic clusters. Subsequent treatment with TPA resulted in no additional change in
CaMKII distribution, indicating that the PKC-induced accumulation of CaMKII involves an association with spine F-actin. In contrast, loss of
F-actin did not inhibit the ability of PKC to disperse NMDA receptors.
Thus, PKC-induced dispersal of NMDA receptors is independent of F-actin
and independent of the translocation of CaMKII. The
nonsynaptic clusters of NMDA receptor that are present in low numbers
under our control conditions and at higher numbers in immature neurons
or in latrunculin-treated neurons also largely dispersed with PKC
activation (data not shown).
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Figure 6.
Dependence of CaMKII translocation but not NMDAR
translocation on filamentous actin. Neurons were treated for 9 hr with
latrunculin A (+LAT) to depolymerize actin,
treated for 45 min with TPA as indicated (+TPA), fixed,
and immunolabeled for CaMKII or NR1 (green)
and synapsin (Syn; red). a,
b, In latrunculin-treated neurons, CaMKII was diffusely
localized, and activation of PKC was unable to induce synaptic
accumulation. c, d, In latrunculin-treated neurons, NR1
was clustered at synaptic and nonsynaptic sites. PKC activation induced
a loss of synaptic and nonsynaptic clusters and a redistribution to a
dispersed plasma membrane-associated pattern even in the absence of
detectable F-actin. Boxed regions in a-d are
shown below at higher magnification. Scale bar, 10 µm.
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Cell-surface association of NMDA receptors
To assess the level of surface expression of NR1 after TPA
treatment, we subjected live neurons to the extracellular protease chymotrypsin before harvesting and Western blot analysis (Hall and
Soderling, 1997). In neuron culture extracts, immunoblotting for NR1
reveals a strong band at ~120 kDa (Fig.
7). When intact neurons are subjected to
the extracellular proteolytic activity of chymotrypsin, the
extracellular region of any NR1 protein on the cell surface is cleaved
and the immunoblot signal at ~120 kDa is decreased proportionally to
the percentage of NR1 on the cell surface. Tau, an intracellular
cytoskeletal protein, is inaccessible to chymotrypsin. Previous results
using this method indicate that NR1 is present in significant
intracellular pools in immature or low-density neurons with a
nonsynaptic immunostaining pattern (42% surface), but largely on the
surface of neurons with a highly synaptic immunostaining pattern (87%
surface) (Crump et al., 2001). Our finding here that 84% of the NR1
was cleaved and thus surface associated in neurons with the highly
synaptic NMDA receptor pattern is in agreement with these previous
results. TPA treatment did not change the percentage of surface NR1;
84% of total cellular NR1 was still accessible to extracellular
protease (average of three experiments each). The total amount of NR1
also did not change with TPA treatment. Sister neurons from the
TPA-treated group were immunolabeled to confirm the predominantly
extrasynaptic localization of NR1. Thus, although TPA induces a
redistribution of NR1 away from synapses, the redistributed NR1 is on
the cell surface. These experiments are supported by the immunolabeling pattern for NR1 throughout the exposure to phorbol esters (Figs. 1f, 3a). NR1 appeared to be associated with
plasma membrane; at no time were nonsynaptic clusters characteristic of
endosomes observed. Direct cell-surface labeling of live or
nonpermeabilized neurons with commercially available antibodies against
NR1 was not possible, perhaps because of limited accessibility of the native NMDA receptor complex in neurons.
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Figure 7.
Cell-surface association of clustered and
dispersed NMDAR. Intact hippocampal neurons were treated with TPA (30 min) and then with extracellular protease chymotrypsin (10 min) as
indicated before cultures were harvested for Western blot analysis.
Immunoblotting for NR1 revealed a strong band at ~120 kDa, as
expected. After chymotrypsin treatment, the extracellular region of
cell-surface NR1 is cleaved and the native ~120 kDa signal is
decreased. Tau, an intracellular cytoskeletal protein, is inaccessible
to chymotrypsin and was used as a control for protein loading between
conditions. The percentage of cleaved and thus surface-accessible NR1
was 84% for both control and TPA-treated neurons (average of 3 experiments each).
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Neuroprotective effect of PKC-induced synaptic remodeling
Excessive calcium entry through NMDA receptors is a major trigger
of neuronal cell death (Rothman and Olney, 1995). In low-density hippocampal cultures under conditions of spontaneous activity, NMDA
receptors are primarily extrasynaptic and neurons exhibit limited
toxicity in response to a high-potassium insult (Crump et al., 2001).
Chronic blockade of NMDA receptors results in a large increase in
synaptic targeting of NMDA receptors (the baseline condition for the
experiments described above) and a concomitant increase in
excitotoxicity after antagonist washout (Crump et al., 2001). In
agreement with these previous studies, in response to a short pulse of
high potassium to induce synaptic release of glutamate, APV-pretreated
neurons exhibited greater toxicity (43.7 ± 2.8% cell viability)
than neurons cultured without APV (62.2 ± 4.0% viability;
t test; p < 0.01; n = 8 coverslips) (Fig. 8a). This
enhanced toxicity was dependent on NMDA receptor function, as indicated
by sensitivity to APV during the toxicity assay (Fig. 8a,
compare columns 3 and 4: the decrease in
viability from >90% in untreated neurons to ~60% after treatment
with high K+ was NMDAR-independent, but
the additional decrease in viability of APV-pretreated cells to ~40%
was NMDAR-dependent). We subsequently asked whether dispersing NMDAR
from postsynaptic sites by TPA treatment would be neuroprotective. In
APV-pretreated neurons with highly synaptic NMDAR clusters, treatment
with TPA and concomitant dispersal of NMDAR (as in Fig. 1)
significantly reduced excitotoxicity (63.2 ± 2.6% cell
viability; t test; p < 0.01 compared with
APV group; n = 8) (Fig. 8, column 2 in
b vs column 3 in a). In contrast, TPA
treatment had no effect on excitotoxicity in low-density neurons cultured without APV and lacking synaptic NMDA receptors clusters (Fig.
8, column 1 in b vs column 2 in
a). These results suggest that the TPA-induced
neuroprotection is attributable to the dispersal of NMDAR in
APV-pretreated neurons rather than other effects of TPA that would
presumably also occur in neurons cultured without APV.
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Figure 8.
Neuroprotective effect of PKC-induced
synaptic remodeling. Neurons were cultured at low density in the
presence (gray bars) or absence (black bars) of
APV and were treated with TPA for 45 min or untreated, as indicated.
Neurons were then assayed for excitotoxicity by washout of the APV and
TPA, exposure to high-K+ buffer, and
determination of viability by Trypan blue exclusion. a,
Neurons cultured chronically with APV exhibited greater toxicity than
neurons cultured without APV (t test;
p < 0.01), correlating with a higher level of
synaptic NMDAR, as reported previously (Crump et al., 2001). This
enhanced toxicity of the chronic APV group was mediated by NMDAR, as
indicated by sensitivity to APV during the toxicity assay.
b, TPA treatment of the APV group partially protected
the neurons from excitotoxicity (p < 0.01)
by an amount corresponding to the NMDAR-mediated component. TPA was not
protective in the no-APV group with the much lower levels of synaptic
NMDAR, suggesting that the protective effect of TPA was attributable to
the dispersion of synaptic NMDAR in the chronic APV group.
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Live visualization of NMDAR dispersion by PKC
To visualize the effect of PKC activity on NMDAR distribution
without constraints imposed by antibody-based methods, we used a
GFP-tagged NR1 subunit. Coexpression of NR1-GFP and NR2A at low
expression levels in APV-treated cultured hippocampal neurons results
in synaptic clustering of the NR1-GFP (Fig.
9a,a') (Crump et al., 2001).
In all experiments, the distribution of transfected NR1-GFP was similar
to that of endogenous NR1 visualized by immunolabeling. Immunolabeling
of NR1-GFP-expressing neurons for CaMKII shows clearly in a single
neuron the differential distributions implied by the separate antibody
labeling experiments: NR1-GFP was highly clustered on dendritic spines,
whereas CaMKII showed some concentration in these spines but was also
present diffusely throughout the neuron (Fig. 9b,b'). TPA
treatment resulted in a reversal of the distribution patterns: NR1-GFP
became diffusely distributed throughout the dendrite, with minor
concentrations remaining at dendritic spines, whereas CaMKII became
highly concentrated in dendritic spines and showed reduced levels in
shafts (Fig. 9c,c').
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Figure 9.
PKC-induced transposition of NMDAR and CaMKII
distributions and visualization of NMDAR dispersal in live neurons.
a-c, Neurons were transfected at 1 week with NR1-GFP
and NR2A, cultured for another 2 weeks, treated with TPA as indicated,
fixed, and immunolabeled for synaptophysin (Syn;
a, a') or CaMKII (b, b', c, c').
a, a', Recombinant NR1-GFP clustered on dendritic spines
opposite synaptic terminals. b, b', NR1-GFP was highly
concentrated in dendritic spines in control (Con)
neurons, and CaMKII was detected in the same spines but also at high
levels throughout the dendrite shaft. c, c', In
TPA-treated neurons, the distribution patterns of NR1-GFP and CaMKII
were reversed relative to controls. CaMKII now clustered strongly on
dendritic spines, and NR1-GFP was present at high levels in both spines
and shafts. d-f, Neurons were transfected with NR1-GFP
and NR2A at plating and imaged at 3 weeks before and 30 min after
addition of TPA. As expected on the basis of the population analyses,
NR1-GFP dispersed after TPA treatment. f, Analysis of
the spine/shaft fluorescence intensity ratio in individual dendritic
spines revealed a consistent decrease after TPA treatment (control
mean ± SEM, 3.2 ± 0.1; TPA mean ± SEM, 1.5 ± 0.1; paired t test; p < 0.01;
n = 45 spines from 3 neurons). Scale bars, 10 µm.
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NR1-GFP expression allowed us to visualize the effects of PKC
activation on NMDAR distribution in single neurons over time. A 30 min
treatment with TPA induced a dramatic dispersal of spiny NR1-GFP
clusters visualized in the same neuron before and after TPA treatment
(Fig. 9d,e), as expected on the basis of the population analyses. There appeared to be both a decrease in fluorescence in the
dendritic spines and an increase in fluorescence in the dendrite
shafts. The average NR1-GFP fluorescence intensity ratio in the same
set of dendrite spines relative to the dendrite shaft decreased from
3.2 ± 0.1 before TPA addition to 1.5 ± 0.1 after TPA
addition (paired t test; p < 0.01;
n = 45 spines from three neurons) (Fig.
9f). Thus, PKC induces dispersal of existing NMDA receptors away from synaptic sites to the extrasynaptic membrane. The
spine/shaft intensity values indicate a more than twofold decrease in
the ratio of synaptic to extrasynaptic tagged NMDA receptor after PKC activation.
| |
DISCUSSION |
We show here that CaMKII and NMDA receptors exhibit rapid and
reciprocal redistribution to and from synapses in response to selective
activation of one kinase, PKC. NMDA receptors dispersed and CaMKII
clustered with approximately half-maximal effects at 10 min of
treatment with phorbol esters, and both effects were rapidly
reversible. PKC also induced a slight enhancement of filamentous actin
at synapses but no change in the density of presynaptic terminals,
dendritic spines, or postsynaptic clusters of the scaffolding molecule
PSD-95 and no change in AMPA receptor localization. PKC-induced clustering of CaMKII was dependent on the presence of F-actin, whereas
dispersal of NMDA receptors was independent of F-actin. Live cell
visualization of PKC-induced redistribution of NR1-GFP revealed a
decrease in NR1-GFP synaptic to extrasynaptic ratio in individual
dendrites over time. NMDA receptors showed no net internalization but
redistributed to the extrasynaptic plasma membrane after PKC
activation. Consistent with the decrease in synaptic NMDA receptor
density, pretreatment with phorbol esters protected neurons against
NMDA-mediated excitotoxicity. These results reveal a surprisingly
dynamic nature to the molecular composition of glutamatergic synapses,
not just with respect to AMPA receptor as shown in many previous
studies but also with respect to NMDA receptor and endogenous CaMKII.
Mechanisms of postsynaptic remodeling by PKC
The postsynaptic density is a highly interconnected network of
proteins in which each component binds with high affinity to several
other components. NMDA receptor subunits and CaMKII/ all have
multiple interacting partners in the PSD. NR1 binds
Ca2+/CaM, the actin-binding proteins
-actinin and spectrin, and the A-kinase anchoring protein (AKAP)
yotiao (Wyszynski et al., 1997; Lin et al., 1998; Wechsler and
Teichberg, 1998; Westphal et al., 1999). NR2A and NR2B bind spectrin
and the PDZ domain proteins PSD-95/SAP90, SAP102, PSD-93/chapsyn-110,
S-SCAM, and mLin7 (Wechsler and Teichberg, 1998; Hirao et al., 2000;
Setou et al., 2000; Sheng and Pak, 2000). CaMKII, through
interaction with CaMKII, binds actin (Shen et al., 1998) and
directly binds Ca2+/CaM, -actinin,
densin-180, and SynGAP (Strack et al., 2000b; Li et al., 2001;
Walikonis et al., 2001). Furthermore, CaMKII binds NR2A/B with high
affinity (Gardoni et al., 2000; Strack et al., 2000a). Thus, it is
likely that a change in the affinity of multiple interactions is
involved in the synaptic remodeling induced by PKC.
The mechanisms for localizing NMDA receptors to synapses are not well
understood. Evidence from genetically targeted mice lacking the C
termini of NR2A or NR2B indicates a partial role for the NR2A/B C
termini in synaptic localization of NMDA receptors (Mori et al., 1998;
Steigerwald et al., 2000). NR1, NR2A, and NR2B are all substrates of
PKC in vitro, and all show increased phosphorylation after
treatment of neurons with phorbol esters (Tingley et al., 1993; Hall
and Soderling, 1997; Leonard and Hell, 1997). We attempted to determine
whether PKC disrupts the interactions of recombinant NR2A and PSD-95 in
heterologous systems, but we could find no consistent evidence for such
a direct mechanism (data not shown). Thus, although we have ruled out
any requirement for an intermediary tyrosine kinase (Fig. 4,
TPA/Lav A column), there may be other
intermediary signaling proteins specific to neurons that mediate
PKC-induced disruption of NR2 binding to PSD-95. Alternatively, it may
be that the interaction between NR2A and PSD-95 is not a major force
for anchoring synaptic NMDA receptors, and that their dissociation
occurs as a consequence of direct disruption of other associations of
NR2 or NR1 with PSD components.
The NR1 subunit of the NMDA receptor has multiple possible interactions
with PSD proteins, some of which could be regulated by PKC. In the NR1
subunit, the alternatively spliced C1 exon contains the major sites of
PKC phosphorylation (Tingley et al., 1997). Homomeric NR1A containing
the C1 exon is trapped in the endoplasmic reticulum (ER), and PKC
phosphorylation adjacent to the ER retention signal promotes
cell-surface delivery of fusion proteins containing the NR1 C1 exon
(Scott et al., 2001). In our experiments, the native NMDA receptors
were already efficiently localized to the cell surface, and PKC did not
change the amount or percentage of NR1 on the cell surface. PKC reduces
binding of NR1 to -actinin (Lu et al., 2000) and to spectrin
(Wechsler and Teichberg, 1998), but our experiments with latrunculin
(Fig. 6) rule out a major role for actin-dependent proteins. Another interaction that is potentially important in NMDAR dispersal is the
binding of NR1 via the C1 exon to the AKAP yotiao (Lin et al., 1998).
Thus, PKC phosphorylation of NR1-C1 might release NR1 from binding to
yotiao. Furthermore, because yotiao also binds PKA (Westphal et al.,
1999) and PKA activity is necessary to maintain synaptic clusters of
NMDAR (Crump et al., 2001), disruption of this interaction could lead
to dispersal both through direct release of NR1 and through decreased
local activity of PKA. In our experiments expressing NR1-GFP, the
NR1C-GFP isoform lacking the C1 exon dispersed; however, obtaining
synaptic clustering of any NR1-GFP isoform required a low expression
level, such that the expressed subunits could be associating with
endogenous NR1 containing the C1 exon; therefore, we were unable to
directly test the role of the NR1 C1 exon in PKC dispersion.
Transient translocation of recombinant CaMKII-GFP to the PSD has been
observed in response to stimulation of NMDA receptors in hippocampal
neurons (Shen and Meyer, 1999; Shen et al., 2000). The initial
translocation requires CaM binding to CaMKII, and association for
several minutes requires CaMKII autophosphorylation on Thr286. The
PKC-induced translocation of CaMKII to synapses reported here differs
from these previous findings in several respects. First, the
PKC-induced translocation appears to be more robust and longer-lasting.
These previous studies did not report any effect on localization of
endogenous CaMKII, and it is possible that the high levels of
overexpression might have induced some nonphysiological associations.
Second, PKC-induced translocation was not inhibited by KN62, a compound
that inhibits CaMKII kinase activity and autophosphorylation
competitively with CaM (Tokumitsu et al., 1990). Third, CaMKII can
bind directly to NR2A and/or NR2B (Strack et al., 2000b; Gardoni et
al., 2001), and it has been reported recently that CaMKII binding to
NR2B is necessary for the glutamate-induced synaptic translocation of
CaMKII-GFP (Bayer et al., 2001). The simultaneous dispersal of NR2B
away from synapses in our experiments, however, would preclude such a
mechanism for PKC-induced synaptic translocation of CaMKII. Thus,
different molecular associations appear to underlie the synaptic
accumulation of CaMKII in these two paradigms.
Physiological significance of postsynaptic remodeling by PKC
There are conflicting reports of the specific effects of PKC on
the NMDAR-mediated component of synaptic transmission in hippocampal neurons. As predicted by our results, Markram and Segal (1992) found
that phorbol esters had no effect on the fast AMPAR-mediated component
of synaptic transmission but suppressed the NMDAR-mediated component of
synaptic transmission in CA1 neurons in hippocampal slice. Other
groups, however (Lozovaya and Klee, 1995), have reported that phorbol
esters enhance EPSCs, including the NMDAR-mediated component, in CA1
neurons in slice. Part of this confusion may be attributable to the
enhancement of presynaptic vesicle fusion by PKC (Malenka et al., 1986;
Parfitt and Madison, 1993). In addition, PKC can increase whole-cell
responses to NMDA in neurons. This increased agonist response has been
ascribed variously to reduction of voltage-dependent
Mg2+ block (Chen and Huang, 1992),
increased probability of channel opening through a mechanism requiring
activity of the tyrosine kinase src (Lu et al., 1999), and an increase
in the number of functional channels on the neuronal surface (Lan et
al., 2001). The PKC-induced dispersal of NMDA receptors reported here
would be predicted to have no effect on the whole-cell response to NMDA or perhaps to mediate a slight increase caused by enhanced
accessibility of the channels to agonist. The major effect of the PKC
dispersal would be to decrease the NMDAR-mediated response to synaptic
transmission, as supported by the enhanced excitotoxicity in response
to high-K+ stimulation (Fig. 8).
PKC-mediated dispersal of synaptic NMDA receptors could be a mechanism
underlying long-term depression (LTD) of the NMDA component of synaptic
transmission. Excitatory synaptic activity activates PKC via calcium
entry through NMDA receptors and via group I metabotropic glutamate
receptor-mediated activation of phospholipase C. Low-frequency stimulation induces LTD of both AMPA- and NMDA-mediated components of
synaptic transmission in hippocampal CA1 neurons (Selig et al., 1995).
LTD of the AMPA-mediated component is accompanied by net endocytosis of
AMPA receptors from synapses in hippocampal cultures (Carroll et al.,
1999). Internalization is also promoted by phorbol esters (Chung et
al., 2000). Our results suggest that LTD of the NMDA component might
occur by PKC-mediated dispersal of NMDA receptors from the synaptic to
extrasynaptic plasma membrane.
Considering the dramatic effects on localization of both
NMDA receptors and CaMKII, which are major
signal-transducing proteins of the PSD, PKC-mediated synaptic
remodeling is likely to be a form of metaplasticity. Metaplasticity
refers to the effects of previous activity in regulating the subsequent
ability of a synapse to undergo potentiation or depression in response
to a given stimulus (Abraham and Bear, 1996). Consistent with the
effects of PKC on NMDAR distribution reported here, Stanton (1995)
found that previous activation of PKC with phorbol esters enhanced
LTD in response to low-frequency stimulation and inhibited induction of
long-term potentiation in response to high-frequency stimulation in CA1 neurons. The PKC-induced increase in levels of CaMKII at the synapse, however, might function in an opposing manner to enhance potentiation. CaMKII increases AMPAR-mediated responses through direct
phosphorylation of AMPA receptors (Barria et al., 1997) and through
promotion of AMPA receptor insertion (Hayashi et al., 2000). Indeed,
other more complex forms of metaplasticity activated by group I
metabotropic receptors and requiring PKC activity have been described
previously (Bortolotto and Collingridge, 2000). The precise form of
metaplasticity may depend on the route of PKC activation and on
cross-talk with other signaling pathways to regulate the kinetics and
spatial redistribution of both NMDA receptors and CaMKII. Current
evidence indicates that synaptic targeting of NMDA receptors is
inhibited by PKC (this work) but promoted by PKA (Crump et al., 2001),
whereas synaptic targeting of CaMKII is promoted both by PKC (this
work) and by autophosphorylation (Shen et al., 2000). Defining the
precise regulatory pathways for dynamic trafficking of kinases and
neurotransmitter receptors, including AMPA and NMDA, will be a
necessary part of understanding mechanisms of synaptic plasticity.
| |
FOOTNOTES |
Received Oct. 25, 2001; revised Dec. 19, 2001; accepted Dec. 20, 2001.
This work was supported by National Institutes of Health Grant NS33184
and the Pew Charitable Trust. We thank Huaiyang Wu for excellent
preparation of neuron cultures.
Correspondence should be addressed to Ann Marie Craig, Department of
Anatomy and Neurobiology, Washington University School of Medicine, 660 South Euclid Avenue, Box 8108, St. Louis, MO 63110. E-mail:
acraig{at}thalamus.wustl.edu.
A. Rao's present address: Neuron, Cell Press, 1100 Massachusetts
Avenue, Cambridge, MA 02138.
| |
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