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The Journal of Neuroscience, April 15, 2002, 22(8):3005-3015
A Developmental Switch of AMPA Receptor Subunits in Neocortical
Pyramidal Neurons
Sanjay S.
Kumar,
Alberto
Bacci,
Viktor
Kharazia, and
John R.
Huguenard
Department of Neurology and Neurological Sciences, Stanford
University Medical Center, Stanford, California 94305-5122
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ABSTRACT |
AMPA receptors mediate most of the fast excitatory
neurotransmission in the brain, and those lacking the glutamate
receptor 2 (GluR2) subunit are Ca2+-permeable and
expressed in cortical structures primarily by inhibitory interneurons.
Here we report that synaptic AMPA receptors of excitatory layer 5 pyramidal neurons in the rat neocortex are deficient in GluR2 in early
development, approximately before postnatal day 16, as evidenced by
their inwardly rectifying current-voltage relationship, blockade of
AMPA receptor-mediated EPSCs by external and internal polyamines,
permeability to Ca2+, and GluR2 immunoreactivity.
Overall, these results indicate that neocortical pyramidal neurons
undergo a developmental switch in the Ca2+
permeability of their AMPA receptors through an alteration of their
subunit composition. This has important implications for plasticity and neurotoxicity.
Key words:
AMPA receptors; GluR2 subunit; Ca2+
permeability; pyramidal neurons; neocortex; developmental switch
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INTRODUCTION |
Several important aspects of
neurotransmitter receptor function rely on the underlying subunit
composition. For example, ligand affinity and ion conductance
properties such as gating, permeation, and rectification are all
affected by alterations in receptor subunits (Hollmann and Heinemann,
1994 ; Angulo et al., 1997). Channels with differing biophysical
properties arise from the combination of distinct subunits, resulting
in a surprisingly heterogeneous population of receptor subtypes
expressed in unique patterns in the brain. The AMPA class of ionotropic
glutamate receptors, which mediate fast excitatory synaptic
transmission in the neocortex, are heteromultimeric structures
comprised of glutamate receptor subunits 1-4 (GluR1-4) with varying
stoichiometries (Hollmann and Heinemann, 1994). AMPA receptors (AMPARs)
that lack the GluR2 subunit have traditionally been associated with
inhibitory interneurons (McBain and Dingledine, 1993; Jonas et al.,
1994; Geiger et al., 1995; Zhou and Hablitz, 1998; Yin et al., 1999) and have been shown to be permeable to
Ca2+ (Jonas and Burnashev, 1995; Geiger et
al., 1995; Gu et al., 1996; Washburn et al., 1997). Whether AMPARs
located at excitatory synapses on principal neurons are also permeable
to Ca2+ remains unknown and may be of
importance, given the diverse intracellular effects of
Ca2+ as a ubiquitous second messenger in
development (Aamodt and Constantine-Paton, 1999), synaptic plasticity
(Malenka et al., 1989; Jonas and Burnashev, 1995; Jia et al., 1996;
Mahanty and Sah, 1998; Rohrbough and Spitzer, 1999; Liu and Cull-Candy,
2000), and excitotoxicity (Prince and Connors, 1984; Swann et al.,
1993; Schwartzkroin, 1995).
Using the commissural connections of the corpus callosum as a model
system for intracortical (corticocortical) excitation, we tested this
hypothesis by examining whether the functional properties of synaptic
AMPARs on layer 5 pyramidal neurons changed with respect to the GluR2
subunit during early postnatal development [postnatal day 13 (P13) to
P21]. In this report, GluR2 refers to the edited version of the
subunit at its Gln/Arg site. Most (>99%) GluR2 (GluRB) subunits
expressed in the brain are edited at this position to an Arg residue.
Such edited subunits, unlike the unedited (Gln) forms, confer
Ca2+ impermeability to heteromeric
receptors (Hollmann et al., 1991; Burnashev et al., 1992). Changes in
subunit composition of these receptors were assayed using known
biophysical and pharmacological properties of GluR2-containing and
-lacking AMPARs together with immunohistochemistry to estimate overall
levels of GluR2 expression in the neurons.
Ca2+ permeability through these receptors
was determined directly at the level of the synapse using ion
substitution experiments.
Our results support the conclusion that during early development,
synaptic AMPARs on neocortical pyramidal neurons undergo a switch in
their functional properties by either altering their subunit
composition to incorporate GluR2 or changing their stoichiometry to
increase the copy number of the subunit (Washburn et al., 1997) and
consequently modifying their Ca2+ permeability.
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MATERIALS AND METHODS |
In vitro slice preparation and electrophysiology.
Coronal slices (300 µm) were cut from brains of Sprague Dawley rats,
ranging in age between P13 and P21, anesthetized with pentobarbital (50 mg/kg). These were prepared with a vibratome in a chilled (4°C) low-Ca2+,
low-Na+ "cutting solution" containing
(in mM): 234 sucrose, 11 glucose, 24 NaHCO3, 2.5 KCl, 1.25 NaH2PO4, 10 MgSO4, and 0.5 CaCl2
equilibrated with a 95 and 5% mixture of O2 and
CO2. Slices were allowed to equilibrate in
oxygenated artificial CSF (ACSF; in mM: 126 NaCl, 26 NaHCO3, 2.5 KCl, 1.25 NaH2PO4, 2 MgCl2, 2 CaCl2, and 10 glucose, pH 7.4) first at 32°C for 1 hr and subsequently at room
temperature before being transferred to the recording chamber.
Recordings were obtained at 32 ± 1°C from layer 5 pyramidal
neurons in the agranular frontal cortex (Paxinos and Watson, 1986),
chosen to take advantage of the optimized intrahemispheric connectivity through the callosum in this region, using a visualized infrared setup such that cell morphology and location within the various cortical lamina could be identified. Recording electrodes (1.2-2 µm
tip diameters, 3-6 M ) contained (in mM): 120 cesium
gluconate, 1 MgCl2, 1 CaCl2, 11 KCl, 10 HEPES, 2 NaATP, 0.3 NaGTP, 1 N-(2,6-dimethylphenylcarbamoylmethyl) triethylammonium
bromide, 11 EGTA, pH 7.3 (corrected with Cs-OH, 290 mOsm), and
0.05 spermine (in experiments indicated). Slices were maintained in
oxygenated (95% O2 and 5%
CO2) ACSF, and drugs and chemicals were applied
through the perfusate (2 ml/min).
Concentric bipolar electrodes (CB-XRC75; Frederick Haer & Co.) with 75 µm tip diameters were positioned on the callosal tract, intracortically in close proximity to the recorded neuron (Fig. 1A), or
both, and constant current pulses 50-300 µsec in duration and
100-500 µA in amplitude were applied at low frequencies (0.1-0.3 Hz). Callosal stimulation potentially activates fibers in both orthodromic and antidromic directions, each of which in turn activates monosynaptic excitatory connections onto the recorded pyramidal neuron
(Kumar and Huguenard, 2001). Thus, this model consists of activating a
well defined, relatively homogeneous population of intracortical
excitatory connections. Stimulation parameters were determined by
increasing current strength until postsynaptic responses could be
evoked and were held constant at ~1.2 times the threshold for
obtaining a detectable response throughout the remainder of the
experiment (thresholds were characterized by a large proportion of
failures; Dobrunz and Stevens, 1997). EPSCs were recorded with an
Axopatch-1D amplifier (Axon Instruments, Foster City, CA) and pClamp
software (Axon Instruments), filtered at 1-2 kHz, digitized at 10 kHz,
and stored on VHS videotapes (Neurocorder DR-484; Neuro Data Instrument
Corp.). Series resistance was monitored continuously, and those
experiments in which this parameter changed by >20% were rejected. No
series resistance compensation was used.
Time constants for PSCs were obtained from single exponential fits of
averaged records using Clampfit (Axon Instruments). Traces shown in the
figures are averages of 10-20 consecutive responses (at 0.33 Hz), and
all values are expressed as mean ± SEM. I-V curves
were recorded by changing membrane potential according to a
predetermined randomized sequence to avoid discrepancies associated
with any long-term changes in the responses. Statistical differences
were measured using the Student's t test unless indicated otherwise. The following compounds were bath applied as required for
specific protocols:
D(-)-2-amino-5-phosphonopentanoic acid (D-APV),
2,3-dihydro-6-nitro-7-sulfamoyl-benzo(F)quinoxaline (NBQX, diluted
in dimethylsulfoxide, <0.1% final concentration), picrotoxin (all
from Research Biochemicals/Sigma, St. Louis, MO), and
N-(4-hydroxyphenylpropanoyl)-spermine trihydrochloride
(NHPP-spermine; Tocris Cookson; made fresh on the day of use).
Histology. Cytoplasmic GluR2 levels in pyramidal neurons
were estimated under two different conditions: (1) in slices in which pyramidal cells were filled with Biocytin (via the internal solution, 0.05%; Sigma) during electrophysiology and (2) in sections obtained from intact post-fixed brains using an unbiased sample of cells in the
corresponding anatomical region. A monoclonal antibody that recognized
a tertiary structure of a 256-residue fragment of the N terminus,
unique to GluR2 (MAB397, 1:1500; Chemicon, Temecula, CA) was used in
both cases. This antibody, previously characterized as 6C4, has been
shown not to cross-react with any detectable levels of other
AMPA/kainate subunits on Western blots or immunocytochemical tests
performed on human embryonic kidney 293 cells that were transfected
with corresponding cDNAs (Vissavajjhala et al., 1996).
After electrophysiology, slices were fixed overnight in 4%
paraformaldehyde in phosphate buffer (PB), pH 7.4, at 4°C before
being cut into 40-µm-thick serial sections on a Cryo-Histomat sliding
microtome and collected in PB. To obtain an anatomical confirmation of
the shape, size, and location of recorded pyramidal neurons, sections
were incubated in an avidin-biotin HRP complex (ABC kit, PK-4000;
Vector Laboratories, Burlingame, CA), and the peroxidase product was
histochemically visualized using diaminobenzidine. Sections containing
biocytin-filled neurons were incubated sequentially in 50% ethanol (20 min) and 10% normal donkey serum (in PBS for 30 min to block
nonspecific labeling) with an intermittent PBS rinse followed by a
final overnight incubation in a mixture of streptavidin-Texas Red
conjugate (Vector Laboratories; 1:500) and the primary (anti-GluR2)
antibody. This was followed by a 2 hr incubation with secondary donkey
anti-mouse antibody tagged with fluorescein (Jackson
ImmunoResearch, West Grove, PA; 1:250) on the following day. Sections
were mounted on slides using standard histological mounting media and
coverslipped for microscopy.
A method of quantification was chosen that minimized errors in the
estimation of GluR2 immunoreactivity that might arise from age-dependent variations such as in fixation and antibody binding within different tissues. Each section served as its own control, and
data are presented as the difference between averaged
immunoreactivities of the biocytin-filled cells and the surrounding
neuropil (background) in respective sections (Fig.
2C,D).
Changes in coexpression of GluR2 and GluR1(4) subunits (expressed as
ratios) were assayed in a population of pyramidal cells from the same
cortical region used for electrophysiology in intact brains from four
animals aged P12 (two) and P21 (two), respectively. After deep
anesthesia (Nembutal, 80 mg/kg), animals were perfused with 4%
paraformaldehyde in PB via the aorta (10 min with flushes of saline
before and after fixation). Brains were subsequently removed and
immersed overnight in 30% sucrose in PB at 4°C until the following
day, when frozen sections 40 µm thick were cut using a sliding
microtome. Nonadjacent serial sections were processed for double
GluR1(4) and GluR2 immunofluorescence using the same procedure for
biocytin-filled neurons and GluR2 described above, except for the
addition of a polyclonal GluR1 or GluR4 antibody (Chemicon; 1:250 in
PBS for GluR1 and 1:500 for GluR4) to the primary mixture. GluR1(4)
immunoreactivity was visualized using a 2 hr incubation with
biotin-conjugated donkey anti-rabbit IgG (Jackson ImmunoResearch; 1:250
in PBS), followed by incubation with streptavidin-Texas Red conjugate
(Vector Laboratories; 1:500 in PBS) for an additional 2 hr. Sections
were mounted on slides and coverslipped for microscopy using
Vectashield mounting medium.
Double immunofluorescence was assessed with a laser confocal microscope
[Molecular Dynamics (Sunnyvale, CA) 2010 for the biocytin study and
Bio-Rad (Hercules, CA) Radiance 2000 for GluR2 versus GluR1(4)].
Cross-talk between channels, especially bleed-through of the Texas Red
[biocytin or GluR1(4)] signal to the FITC channel (GluR2), was
minimized using a bandpass 530 ± 15 nm emission filter for FITC
and a long-pass 590 nm filter for the Texas Red channel. Adjacent
sections were routinely stained with thionin to reveal cortical
lamination (Fig. 1C). We assumed that somatic measurements of immunofluorescence are an indicator of overall levels of GluR2 expression within a given neuron. The intensity of immunofluorescence in biocytin-labeled neurons was determined from the averaged gray-scale value (0-255, 8 bit) of 4 measurements within the perikaryon (Fig. 2C2D2) using NIH Image software.
GluR2/1 or GluR2/4 double immunofluorescence of pyramidal cells in
sections from intact brains was obtained using 24 bit red-green-blue
images (0.04 mm2) using SigmaScan software
(version 5; SPSS Inc, Chicago, IL).
Ion exchange experiments.
High-Ca2+ solutions were applied via a
local perfusion system that allowed fast exchange of media at the level
of the synapse. The perfusion pipette was placed just above the slice
and positioned such that the flow through the pipette covered a large
portion of the dendritic extent of the cell of interest (see Fig.
5A). Sections were maintained in oxygenated (100%)
HEPES-buffered ringer comprising (in mM): 135 NaCl, 2.5 KCl, 1 MgCl2, 10 HEPES, and 1.8 CaCl2, pH adjusted with NaOH to 7.4 and
osmolarity with sucrose to 290 mOsm to which (in µM): 50 picrotoxin, 40 D-APV, and 0.05 NBQX were added separately. The
1.8 (control), 10, and 30 mM
Ca2+ solutions were identical in
composition to the bathing media except for CaCl2
and NaCl concentrations which varied as (in mM): 1.8 and 135, 10 and 122.7, and 30 and 92.7, respectively.
Miniature EPSCs (mEPSCs) were recorded with (in
µM): 1 tetrodotoxin (TTX), 50 picrotoxin, and
100 D-APV added to the 1.8 and 10 mM Ca2+ solutions.
mEPSCs were analyzed using homemade software (Detector; J. R. Huguenard), and the threshold for their detection was set at 3 × root mean square noise level. Reversal potential
(Erev) values were estimated from
I-V relationships by linear interpolation.
Permeability ratios were computed using ionic activities instead of
concentrations. Activity coefficients ( ) for various ions were
computed according to the methods of Pitzer and Mayorga (1973) and
Ammann et al. (1975). The respective values estimated for
Na+, K+, and
Ca2+ for the different
Ca2+ solutions were as follows: 1.8 mM Ca2+, 0.75, 0.71, and
0.298; 10 mM Ca2+, 0.74, 0.69, and 0.295; and 30 mM Ca2+,
0.71, 0.68, and 0.289. for the internal solution was 0.72. Final
ionic activity for solutions was computed as the product of and the
corresponding molar concentration. The relative permeability of
Ca2+ with respect to
Na+ was estimated from a nonlinear least
squares fit of reversal potential of the AMPAR-mediated component of
the EPSC (as a function of Ca2+ activity)
to the extended constant-field Goldman-Hodgkin-Katz (GHK) equation
(Mayer and Westbrook, 1987, their Eqs. 1-2c).
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RESULTS |
Isolation of synaptically activated AMPAR currents
Whole-cell voltage-clamp recordings were made from visually
identified pyramidal neurons in layer 5 of the agranular frontal cortex
close to midline (Fig.
1A-C). These cells
receive excitatory asymmetric synapses, by way of the corpus callosum,
from pyramids located mainly in layer 5 of the homotopic contralateral
cortex (Jacobson and Trojanowski, 1974; Ivy and Killackey, 1981; Pandya and Seltzer, 1986; Conti and Manzoni, 1994). Callosal projections are
well suited for studying intracortical excitation, because they
terminate exclusively on the dendritic spines of pyramidal neurons
(Globus and Scheibel, 1967) and are amenable to reliable electrical
stimulation (Vogt and Gorman 1982; Kawaguchi, 1992). Near-threshold
(Dobrunz and Stevens, 1997) stimulation of the callosum, to activate
either a single or a small number of axon collaterals, evoked an inward
EPSC in the pyramidal neuron whose peak amplitude averaged 56.5 ± 5.3 pA (n = 31; Fig. 1D). EPSCs were
isolated in 50 µM picrotoxin and a low
concentration (0.1 µM) of the AMPA/kainate
receptor antagonist NBQX. The latter was used to prevent
hyperexcitability that could arise from the complete blockade of
GABAA-mediated inhibition in the tissue.
Inclusion of NBQX in the perfusate reduced the peak synaptic current by ~20%. Cesium ions in the internal solution of the recording
electrode blocked any K+ currents mediated
through postsynaptic GABAB receptor
activation.
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Figure 1.
Synaptically activated AMPA currents in pyramidal
neurons. A-E, Schematic of the model for studying
intracortical excitability and properties of pharmacologically isolated
monosynaptic EPSCs evoked in pyramidal cells during callosal
stimulation. A, Cortical slice preparation used in the
study showing placement of stimulating (S1,
intracortical; S2, callosal) and recording
(R) electrodes; Fr1,
Fr2, frontal cortex areas 1 and 2; CA1,
region of hippocampus; cg, cingulum; cc,
corpus callosum (principal commissural pathway linking both cerebral
hemispheres). Scale bar, 1 mm. B,
High-magnification view (Scale bar, 40 µm) depicting the typical
morphology of the cells used in electrophysiological recordings.
C, Photomicrograph of one such cell (P15) filled with
biocytin and visualized after fixation with diaminobenzidine (Scale
bar, 100 µm) showing extensive arborization of apical and basal dendrites typical of a
pyramidal neuron. C, Left panel, Portion of the adjacent
cortex stained with thionin to reveal cortical lamination. D,
E, Examples of averaged EPSCs from the same neuron evoked by
callosal stimulation (S2) under the indicated
conditions. PTX, Picrotoxin. Note that responses were
evoked with a fixed latency from stimulus onset (filled
triangle) and the late, slowly decaying component at +30 mV in
D was modified by D-APV
(E) indicating activation of NMDA receptors.
Responses in E were mediated entirely by AMPA receptors,
had identical rise-times at ±30 mV, and were best fit with single
exponentials with the indicated time constants. The above approach
(D, E) was used to isolate the pure AMPAR-mediated
component in all subsequent experiments. F, G,
Rectification of AMPAR-mediated EPSCs is dependent on age but is a
property common to synaptic receptors on pyramidal neurons.
F1, F2, Averages of EPSCs
evoked at various holding potentials in the same neurons during
concomitant alternate stimulation of the callosum (filled
arrowheads) and local intracortical excitatory afferents
(open arrowheads). Peak synaptic currents in P13-P15
neurons (F1) were generally smaller at positive
holding potentials than those at corresponding negative levels, in
contrast to P16-P21 neurons (F2), whose EPSCs
had similar amplitudes. Callosally evoked EPSCs showed similar
age-dependent rectification as those evoked via intracortical
stimulation (n = 11). G,
Rectification indices for the two stimulation paradigms were similar
within the respective age groups but differed significantly between age
groups. *p < 0.05; **p < 0.01.
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EPSCs were deemed monosynaptic by virtue of their fixed latency from
stimulus onset (averaged duration between stimulus and response onsets,
6.1 ± 0.2 msec; n = 30) and their ability to follow stimulus trains (1-20 Hz) without changes in their kinetic properties (Kumar and Huguenard, 2001). At positive holding potentials (+30 mV), an outward, late, and slowly decaying component of the EPSC
was revealed. Addition of D-APV (50 µM) to the bathing medium abolished this late
component, thereby confirming the presence of NMDA receptors at these
synapses (Fig. 1E). The pharmacologically isolated,
AMPA/kainate receptor-mediated component averaged 28.9 ± 4.4 pA
(n = 32) in amplitude at  70 mV and had a 10-90%
rise time of 2.3 ± 0.2 msec (see Discussion) and a decay time
constant ( D) of 6.8 ± 0.5 msec. Rise
times (2.7 ± 3.3 msec) and D values (7.2 ± 0.5 msec) at positive holding potentials (+40 to +60 mV) were similar to those isolated at 70 mV (p > 0.1; n = 16), and all responses could be completely
blocked with 10 µM NBQX (data not shown; see
Fig. 5B). Kainate receptor-mediated responses have been
distinguished from those based on AMPARs by their characteristically long decay times at hyperpolarized holding potentials. The
comparatively short D for EPSCs isolated in
this study, together with the knowledge that expression of kainate
receptors in the neocortex is substantially reduced after P7 (Bahn et
al., 1994; Kidd and Isaac, 1999), suggests that these were mediated
predominantly by the AMPA class of glutamate receptors.
Rectification of AMPAR responses in immature cortex
In pyramidal neurons of animals P16 or older, AMPAR-mediated EPSCs
evoked by callosal stimulation were similar in magnitude at
equipotential levels on either side of the reversal potential (0 mV), a
finding consistent with previous observations (Jonas et al., 1994;
Geiger et al., 1995). Surprisingly, however, when recorded in pyramidal
neurons from P13-P15 animals, AMPAR-mediated synaptic currents were
consistently smaller at positive holding potentials compared with
those at corresponding negative levels. The rectification index (RI),
defined as the ratio of AMPA conductances measured at +40 and 70 mV,
was significantly smaller for P13-P15 neurons (0.7 ± 0.11;
n = 12; range, 0.3-1.6) than for P16-P21 neurons
(1.2 ± 0.13; n = 11; range, 0.6-1.8;
p < 0.01).
To determine whether inward rectification in immature neurons was a
cell- or synapse-specific property, i.e., whether it applied specifically to AMPARs located at callosal synapses or more generally to synaptic AMPARs expressed throughout the pyramidal neuron, we
compared the callosally evoked AMPAR-mediated EPSCs with those evoked
during nonspecific activation of excitatory afferents by a second
stimulating electrode placed in close proximity (either on or off
column) to the recording electrode (Fig. 1A).
Synaptic AMPA currents evoked by cortical stimulation were similar to
those evoked by callosal stimulation in terms of 10-90% rise times
(2.3 ± 0.3 vs 2.3 ± 0.2 msec at 70 mV and 2.34 ± 0.3 vs 2.7 ± 3.3 msec between +40 and +60 mV) and
D values (7.1 ± 0.5 vs 6.8 ± 0.5 msec at 70
mV) but had different onset latencies (3.1 ± 0.2 vs 6.1 ± 0.2 msec at 70 mV; n = 14; p < 0.001). Cortically evoked EPSCs showed similar age-dependent
rectification (RI(P13-P15) = 0.61 ± 0.11;
n = 6; range, 0.4-1.1; Fig.
1F1; RI(P16-P21) = 1.13 ± 0.21; n = 10; range, 0.5-2.3; Fig.
1F2) as those evoked by stimulation of the
callosum (RI(P13-P15) = 0.7 ± 0.11;
RI(P16-P21) = 1.2 ± 0.13; Fig.
1G). Although rectification indices of P13-P15 neurons were
significantly smaller than those of P16-P21 neurons for both stimulus
paradigms (p < 0.05 intracortical; p < 0.01 callosal), there was no difference between
callosal or intracortical stimulation with respect to the RIs for
either age group (p > 0.6). Additionally, it
made no difference whether the stimulating electrode was placed on or
off column with reference to the recorded neuron. These results suggest
that at two distinct developmental stages, P13-P15 and P16-P21,
synaptic AMPARs expressed by the pyramidal neurons share a similar
degree of rectification. Further support for a lack of input
specificity derives from the finding that spontaneous AMPAR-mediated
currents, which presumably arise from activation of multiple inputs
onto the recorded pyramidal neurons, displayed age-dependent
rectification similar to that of the evoked responses (Kumar and
Huguenard, 2001).
Thus immature AMPAR-dependent synapses on pyramidal neurons in general
are characterized by inward rectification, in contrast to mature
synapses. Because inward rectification is an attribute of AMPARs
lacking the GluR2 subunit (Jonas et al., 1994; Geiger et al., 1995;
Jonas and Burnashev, 1995; Washburn et al., 1997), we next assayed
GluR2 content via immunocytochemistry to test whether pyramidal neurons
might alter their expression of GluR2 during development.
Developmental changes in GluR2 immunoreactivity in layer 5 pyramidal neurons
We used double immunofluorescence confocal microscopy to assess
GluR2 levels in recorded neurons from each age group. The overall
pattern of GluR2 staining in neocortex was similar to that reported
previously (Vissavajjhala et al., 1996), revealing a laminar
distribution with numerous GluR2-positive pyramidal cells in layers 3 and 5. GluR2 immunoreactivity in recorded biocytin-filled pyramidal
neurons (P14; Fig.
2A1; P18; Fig.
2B1) was comparable with that detected in
neighboring cells in the microscopic field at both ages (Fig.
2A2,B2). However, we found
that older neurons consistently expressed higher GluR2 immunoreactivity
than younger neurons. Representative differences in GluR2
immunofluorescence in these age groups can be seen from overlapped
images in Figure 2, A3, B3,
C3, and D3. Consistent with these
qualitative observations, GluR2 content, measured in terms of somatic
immunoreactivity compared with background (Fig. 2C-D; see
Histology in Materials and Methods), was significantly lower in
P13-P15 biocytin-filled pyramidal neurons than in the P16-P21 cells
(9.7 ± 6.5 vs 32.1 ± 6.3 gray-scale units;
n = 6 and 9, respectively; p < 0.05;
Fig. 2E). Although these immunostaining results do
not directly demonstrate changes in synaptic GluR2 expression, they do
show that this subunit is developmentally regulated in the same layer 5 pyramidal neurons in which functional changes in synaptic AMPA
responses occur.
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Figure 2.
GluR2 expression in pyramidal neurons at different
ages. A, B, Dual-channel images of recorded
biocytin-filled layer 5 pyramidal neurons from P14
(A1-A3) and P18
(B1-B3) animals
immunostained with the GluR2 antibody (A1,
B1, biocytin-Texas Red;
A2, B2, GluR2-FITC;
A3, B3, color overlap).
Note that pyramidal neurons, including biocytin-filled cells
(A2, B2,
arrows), in the older age group show higher levels of
GluR2 immunofluorescence compared with younger under similar conditions
of illumination. Scale bars: A1,
A2, B1,
B2, 50 µm;
A3, B3, 20 µm.
C, D, High-magnification images of young
(C1-C3) and old
(D1-D3) biocytin-filled
neurons showing that although the intracellular level of GluR2-FITC
fluorescence in the young animal (C2) is
comparable with adjacent neuropil and with the intranuclear staining,
it is markedly more intense in the corresponding regions of the older
neuron (C2 vs D2). Note
the absence of cross-talk between Texas Red (C1,
D1) and FITC (C2,
D2) channels. Immunofluorescence was measured at
four locations (C2 and
D2, red circles) within the
perikaryon (outlined with dashed yellow lines), and the
average of these values was used to represent cell brightness (see
Materials and Methods). Scale bars, 10 µm. E, GluR2
levels in P13-P15 (n = 6) and P16-P21
(n = 9) biocytin-filled pyramidal neurons based on
perikaryon immunofluorescence measurements compared with background as
outlined in C, D. F, Changes in GluR2
immunoreactivity relative to coexpressed GluR1 (or 4) measured
separately in a population of layer 5 pyramidal cells from
corresponding cortical regions in intact brain sections of animals at
the indicated ages (P12, n = 142 cells, 11 sections; P21, n = 83 cells, 10 sections).
*p < 0.05; ***p < 0.0001.
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To rule out the possibility that the developmental increase in GluR2
immunoreactivity might simply be a reflection of an overall increased
expression of AMPARs, we simultaneously assayed the coexpression of
other subunits (either GluR1 or GluR4) in a population of layer 5 pyramidal neurons from corresponding cortical regions. The ratio of the
averaged intensities for GluR2 and GluR1 immunofluorescence was
2.0 ± 0.03 (n = 142 cells, 11 sections, two
animals) for P12 animals compared with 2.6 ± 0.1 (n = 83 cells, 10 sections, two animals) for P21
animals, corresponding to a ~30% increase in the GluR2/GluR1 ratio
between these ages (p < 0.0001; t
test; Fig. 2F). In comparison, there was also an
increase in the separately determined GluR2/GluR4 ratio (~14%) at
the corresponding ages (P12, 2.5 ± 0.04; n = 113 cells, eight sections; P21, 2.8 ± 0.05; n = 80 cell, eight sections; p < 0.0001; Fig.
2F). These data suggest that GluR2 levels in
pyramidal cells are developmentally upregulated relative to both GluR1
and GluR4, warranting further functional assays to determine whether
these alterations in relative GluR2 expression are reflected in AMPAR
composition at the synaptic level.
Internal polyamines sustain age-related differences in
rectification properties
Although rectification properties of AMPAR-mediated EPSCs have
commonly been used to indicate Ca2+
permeability and GluR2 stoichiometry, several studies have suggested that inward rectification of AMPARs also depends on endogenous spermine
(a cytoplasmic polyamine) and that this property is lost under
conditions in which polyamines were dialyzed. Conversely, the loss of
rectification could be prevented by the inclusion of spermine in the
pipette (Donevan and Rogawski, 1995; Isa et al., 1995; Kamboj et
al., 1995).
To examine a potential role of intracellular polyamines in the
rectification of AMPAR-dependent EPSCs reported here, we obtained their
I-V relationships in recordings with 50 µM NHPP-spermine (a polyamine with known
intracellular effects on AMPAR-mediated responses; Bahring et al.,
1997) included in the pipette. EPSCs recorded in this series from
pyramidal neurons of P13-P15 animals showed consistent inward
rectification (Fig. 3A). This
was noted by a significant deviation from the linear I-V
slope obtained from inward responses at negative holding potentials
(n = 14 neurons; Fig. 3B). EPSCs had a
reversal potential near 0 mV and, as indicated before, could be
completely blocked by NBQX. In contrast, EPSCs recorded from P16-P21
neurons were nonrectifying (Fig. 3C), and the composite
I-V relationship from eight neurons was slightly outwardly
rectifying (Fig. 3D). The rectification index for P13-P15 neurons was significantly smaller than that for P16-P21 neurons (0.46 ± 0.05 vs 1.08 ± 0.08; p < 0.0001;
Fig. 3E). I-V relationships were recorded ~15
min after break-in to allow sufficient time for diffusion of the
polyamine, and measurements were made from averages of 20 responses
evoked by either callosal or intracortical stimulation. Series
resistance was monitored periodically, and the holding currents at
various membrane potentials were similar for neurons from the different
age groups (p > 0.5, paired t test; Fig. 3F), suggesting minimal contribution of
voltage-clamp errors to the observed differences in rectification.
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Figure 3.
Inclusion of NHPP-spermine (50 µM)
in the pipette does not alter age-dependent differences in
I-V characteristics of AMPAR-mediated EPSCs.
A, Superimposed averaged records of synaptic currents
evoked in a P13 neuron at various holding potentials (70 to +40 mV;
step size, 10 mV; isolated in cocktail solution and 50 µM
D-APV) with the polyamine included in the patch pipette.
The corresponding I-V curve, normalized to the EPSC
amplitude at 70 mV, is shown in the inset.
B, Normalized I-V relationship of the
pooled data taken from P13-P15 neurons showing inward rectification of
the EPSCs. Each point on the plot (open
circle) represents an ensemble average of 14 experiments, and
error bars indicate SEM where this is greater than the size of the
symbol. The dashed line is an extension of the linear
regression fit of data points at negative holding potentials. C,
D, In contrast with A, B, EPSCs
recorded from neurons in an older animal were nonrectifying
(C), and the composite I-V
profile, averaged from eight P16-P21 neurons, was linear throughout
the entire voltage-range (D). E,
F, RIs for the two age groups and averaged holding currents
recorded at various membrane potentials in these experiments,
respectively. ***p < 0.0001.
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The rectification index in younger neurons was smaller with spermine in
the pipette than without the polyamine (0.46 ± 0.05 vs 0.7 ± 0.11); however, the difference was not statistically significant
(p = 0.08) because of the greater variability in
RI when spermine was omitted (range without spermine, 0.3-1.6; range with spermine, 0.09-0.9). These data are consistent with the notion that inclusion of spermine in the pipette can prevent loss of rectification and do not support the hypothesis that variations in
levels of endogenous polyamines can account for the differences in
rectification properties observed between the two age groups.
Selective blockade of AMPAR-mediated EPSCs by polyamines in
immature neurons
AMPARs devoid of GluR2 are unique not only in their rectification
but also in their selective blockade by both external and internal
polyamines (Bowie and Mayer, 1995; Washburn and Dingledine, 1996;
Washburn et al., 1997), although this has not been directly established
for synaptic responses. Sensitivity to extracellular polyamines was
tested by bath application of NHPP-spermine (5 µM).
AMPAR-mediated EPSCs (recorded with polyamine-free patch pipettes) in
the P13-P15 neurons were reversibly blocked by 37.1 ± 8.1%,
(n = 7; p < 0.005; measured in Fig.
4A1,
point 2), whereas those in the P16-P21 age group were
unaffected (1.8 ± 4.6% blockade; n = 7; Fig.
4A2). The differential blockade by
NHPP-spermine seen in these experiments was robust and provides further
support for a low level of GluR2 expression at synapses of pyramidal
neurons in the younger animals. As a further test of the relative
deficiency of GluR2 in AMPARs in P13-P15 neurons, we also examined the
intracellular effects of 50 µM NHPP-spermine on
EPSC amplitude by including it in the patch solution.
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Figure 4.
Effects of extracellular (A)
and intracellular (B) polyamine on EPSC
amplitude. A1, A2, Pooled
data (n = 7) showing the time course of changes in
response amplitudes (percentage of control, 70 mV) of neurons in
different age groups in the presence of 5 µM
NHPP-spermine applied externally at the times indicated (black
bar; 100% = average of all control values). EPSCs in
A1 were blocked by 37.1 ± 8.1% as opposed
to 1.8 ± 4.6% in A2 (values correspond to
the second designated time point in A1,
A2, respectively). Traces
recorded at the times indicated are shown below their respective time
plots. EPSCs in all these experiments were isolated in a cocktail and
D-APV. B1,
B2, Inclusion of NHPP-spermine (50 µM) in the patch solution had differential effects on
EPSCs depending on the developmental age of the animal. Changes in EPSC
amplitude after break-in (t = 0 min;
holding potential, 70 mV, ACSF) from neurons in the younger
(B1; n = 6) and older
(B2; n = 7) age groups under
different experimental conditions are shown. NHPP-spermine reduced the amplitude of evoked responses during both callosal
( ) and intracortical ( ) stimulation in the younger
(B1) but not in the older
(B2) age group. Callosal EPSCs recorded with
polyamine-containing patch electrodes were significantly smaller
compared with those with control solution ( ). Each
point on the plot represents an ensemble average of the
EPSC amplitudes, and error bars indicate SEM. Responses are normalized
to the averaged EPSC at t = 0 min (100%). Series
resistance ( ) in these experiments was constant, as shown in
B1. Traces at the
top of the plots are averaged sample records obtained at
the times indicated.
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Internal polyamines have been shown previously both to prevent
the loss of rectification and to reduce the amplitude of
GluR2-deficient AMPAR-mediated EPSCs (Donevan and Rogawski, 1995;
Kamboj et al., 1995; Koh et al., 1995). Intracellular NHPP-spermine
produced a time-dependent reduction of both callosal and
intracortically evoked EPSCs in P13-P15 neurons
(p < 0.01, repeated measures ANOVA; Fig.
4B1), consistent with passive diffusion of
the polyamine from the recording pipette to the activated synapses. The
relative block stabilized by ~20 min, at which time callosal and
intracortical EPSC amplitudes averaged 53 ± 11.5%
(n = 6) and 47 ± 9.4% (n = 3),
respectively, of their values at break-in (t = 0 min).
Series resistance remained unaltered during the recording sessions, as did callosal responses from sequential recording in neighboring pyramidal neurons in the same sections obtained with polyamine-free patch electrodes. By contrast, in P16-P21 neurons, neither callosal (96 ± 7.8%; n = 7) nor intracortical (121 ± 13.5%; n = 4) EPSCs were reduced by intracellular
NHPP-spermine (p > 0.4, repeated measures
ANOVA; Fig. 4B2). The selective reductions in EPSC amplitude in P13-P15 but not P16-P21 neurons provides direct additional evidence for age-specific, GluR2-mediated differences in the
subunit composition of synaptic AMPARs.
Differences in Ca2+ permeability of AMPARs
in synapses
Previous studies have successfully used outside-out patches,
isolated from the cell soma, to demonstrate
Ca2+ permeability through AMPARs deficient
in the GluR2 subunit (Jonas and Sakmann, 1992; Jonas et al., 1994; Otis
et al., 1995; Itazawa et al., 1997). However, somatic AMPARs on
excitatory neurons in the neocortex are primarily extrasynaptic and
might have a different complement of subunits compared with the ones
located at the synapse (Lerma et al., 1994; Carder, 1997; Yin et al.,
1999; Kumar and Huguenard, 2001). To directly investigate
Ca2+ permeability through these synaptic
receptors, we measured the shift in
Erev of synaptically activated
currents during local perfusion of solutions with different
extracellular calcium concentrations (Fig.
5A; see Ion exchange
experiments in Materials and Methods). Unlike rectification,
Ca2+ permeability of AMPARs is independent
of intracellular polyamines (Gilbertson et al., 1991; Jonas et al.,
1994; Kamboj et al., 1995; Otis et al., 1995). Thus this series of
experiments was performed without spermine in the patch pipette, and
the resultant I-V curves in P13-P15 neurons were not
expected to display prominent rectification.
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Figure 5.
Experimental design and validation of the
procedure used to determine Ca2+ permeability of
synaptic AMPARs. A, Schematic of the experimental
configuration showing relative placements of the intracortical
stimulating electrode and local perfusion pipette with respect to the
patch recording electrode. B, Representative traces of
AMPAR-mediated responses (70 mV) during perfusion of solutions with
different Ca2+ concentrations. Traces
shown are from a P18 animal. Note that it required higher stimulus
intensities to evoke EPSCs in high Ca2+. The
averaged (percent) increments in charge required to elicit responses
when [Ca2+]o was sequentially elevated
from 1.8 to 10 and from 10 to 30 mM were 60.9 and 20.8%,
respectively, for P13-P15 neurons and 70.9 and 41.9%, respectively,
for P16-P21 neurons. Inclusion of 10 µM NBQX in the
local perfusate blocked all EPSCs evoked in high
Ca2+. The numbered responses in
B are overlaid such that the second response is scaled
to match the amplitude of the first response. Note the fixed latency
from stimulus onset for the two responses and the similarity in the
shape of the waveforms. C, D, mEPSC frequency is
increased after local elevation of
[Ca2+]o via the local perfusion
system. C, Representative traces of mEPSCs recorded from
a P19 layer 5 pyramidal neuron in the presence of 1 µM
TTX, 50 µM picrotoxin, and 100 µM APV under
the indicated conditions. D, Time course of changes
taken from a different neuron showing the fast onset and offset of the
altered mEPSC frequency. E, Bar plot of the averaged
mEPSC frequency under different
[Ca2+]o conditions (n = 8 and 5 cells for 10 mM Ca2+ and
wash, respectively) normalized to the mean value in
control. *p < 0.05.
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We first verified that the extracellular
Ca2+ concentration could be effectively
controlled by our local perfusion system. Evidence for successful
solution change included the following: (1) Elevation of
[Ca2+]o
reduced the synaptic response amplitude and increased its activation threshold (Fig. 5B; cf. Otis et al., 1995), consistent with
alteration in both presynaptic and postsynaptic excitability.
[Similarities in latency, rise time and decay between the waveforms
suggest that the same or similar synapses are activated by the
increased stimulus intensity in elevated
[Ca2+]o (Fig.
5B, Overlay).] (2) Ten micromolar NBQX in the
local perfusate completely blocked the synaptic responses, indicating
that the local perfusion system effectively alters the extracellular
environment at the synapse (Fig. 5B). (3) mEPSCs (recorded
in the presence of TTX in both age groups) showed a robust and
reversible increase in frequency when
[Ca2+]o was
altered in the local environment of the recorded neurons (Fig.
5C-E). The time course of change in mEPSC frequency (Fig. 5D) shows the rapid onset and offset of the
Ca2+ exchange. A reversible sixfold
increase in mEPSC frequency was induced when
[Ca2+]o was raised
from 1.8 (control) to 10 mM (n = 8; p < 0.05, paired t test). This result is
consistent with an increase in release probability as expected for
elevated [Ca2+]o
at the level of the synapse. These data suggest that the local perfusion technique can effectively control extracellular environment in general, and
[Ca2+]o in
particular, at the synapse.
I-V relationships for synaptic AMPAR responses in pyramidal
neurons of both age groups were obtained under various
[Ca2+]o [1.8
(normal), 10, and 30 mM].
The Erev in 1.8 mM
[Ca2+]o for
P13-P15 neurons (n = 11) was similar to the value
obtained with P16-P21 neurons (n = 6; 4.8 ± 2.4 vs 7.4 ± 3.3 mV). When [Ca2+]o was
increased to 10 mM and subsequently to 30 mM, Erev shifted slightly in a positive direction to 3.2 ± 2.2 and 0.1 ± 1.6 mV, respectively, in P13-P15 neurons (Fig.
6A,C1). In
contrast, Erev shifted in the opposite
direction to 13.7 ± 3.2 and 30.4 ± 3.3 mV in the older
P16-P21 neurons (Fig. 6B,C2), suggesting relative impermeance of the receptors to
Ca2+. The differences in
Erev were statistically significant
between the two age groups (p < 0.02 and 0.005 for 10 and 30 mM
Ca2+, respectively; Fig.
6D) and among the different
[Ca2+]o for the
P16-P21 but not P13-P15 neurons (p < 0.0005, repeated measures ANOVA). Thus, synaptic AMPAR from only the younger
age group displayed significant Ca2+
permeability. Using the extended GHK constant-field equation (Mayer and
Westbrook, 1987), we estimate that the lack of shift in
Erev as a function of
Ca2+ ionic activities in the younger
neurons reflects a Ca2+ to
Na+ permeability ratio
(PCa/PNa)
of >2.0 (n = 11) compared with a PCa/PNa
ratio of <0.1 (n = 6) for the older neurons recorded
under the same experimental conditions.
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Figure 6.
Differential Ca2+ permeability
of synaptic AMPARs within the identified age groups.
A-C, Families of representative traces (A,
B, ±40 mV; step size, 10 mV) and their corresponding
I-V relationships (C1,
C2) recorded from animals in the two age groups
under various [Ca2+]o conditions. The
asterisks in A indicate the response at a
holding potential of 0 mV. D, Plot of the
Erev values, measured from
I-V relationships, as a function of
[Ca2+]o. Each point
represents the mean of the indicated number of experiments in the
respective age groups. Note the leftward shift in
Erev for the older animals in contrast with
the opposite trend (dashed lines) observed in the
younger animals. Statistical comparisons are between the reversal
potentials for animals in the two age groups. *p < 0.02; **p < 0.005.
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DISCUSSION |
Maturation of neocortical circuitry relies in large measure on
developmentally regulated changes in its presynaptic and postsynaptic elements. Only recently have we begun to understand the underlying cellular mechanisms responsible for these changes and their potential consequences. GluR2-deficient AMPARs exhibiting inward rectification and a polyamine-dependent block have been described in other brain structures (McBain and Dingledine, 1993; Mahanty and Sah, 1998; Yin et
al., 1999) and have been proposed to reside predominantly on inhibitory
GABAergic interneurons (McBain and Dingledine, 1993; Jonas et al.,
1994; Geiger et al., 1995; Itazawa et al., 1997; Zhou and Hablitz,
1998; Yin et al., 1999). We have demonstrated that this deficiency also
applies to synaptic AMPARs of principal neurons during early
development before postnatal day 16. Our conclusions are based on the
observations that (1) the I-V relationships of the isolated
AMPAR component reveal clear differences in rectification properties
between the two age groups considered; and (2) the blocking effects of
either intracellular or extracellular NHPP-spermine (Kamboj et al.,
1995; Mahanty and Sah, 1998; Rozov and Burnashev, 1999) and
permeability to Ca2+ are seen only in
pyramidal neurons from animals belonging to the younger age group.
Because polyamine interaction with AMPARs has been observed solely in
the absence of the GluR2 subunit, this suggests that changes in
rectification noted above are most likely mediated through alterations
in synaptic receptors. The results from experiments using dual
stimulation paradigms and analysis of spontaneously occurring EPSCs
further suggest that the functional properties of synaptically
expressed AMPARs are not input-specific (Kumar and Huguenard,
2001).
To what extent do these changes reflect GluR2 stoichiometry of synaptic
AMPARs? Washburn et al. (1997) argued that the findings of highly
variable rectification and the polyamine block observed among different
cells are inconsistent with a fixed stoichiometry for either
recombinant or native AMPARs. Instead, the number of GluR2 subunits in
individual AMPARs can vary widely. The number of GluR2 subunits in a
receptor thus appears to be the primary factor influencing the degree
of rectification and polyamine sensitivity. Indeed, the variability in
rectification, degree of polyamine block, and GluR2 immunoreactivity we
have observed, compared with other systems or neuron types, support
these conclusions and suggest a low but variable GluR2 stoichiometry
for synaptic AMPARs on P13-P15 pyramidal neurons unlike P16-P21 neurons.
Technical considerations
Changes in I-V relationships might result from
age-dependent differences in the inability to adequately voltage clamp
electrotonically remote synapses. We found that AMPA and NMDA
receptor-mediated components of the EPSC both reversed polarity at the
expected reversal potential (0 mV) in both age groups. This would not
be expected if voltage-clamp reliability was compromised, as might occur, for example, with alterations in K+
channel expression. Furthermore, holding currents at various membrane
potentials for neurons in both age groups were similar, suggesting
minimal contribution of voltage-clamp errors to the observed
rectification. Series resistance and rise times were also similar.
These facts, together with the differential effects of intracellular
spermine on AMPAR-mediated synaptic responses in the two age groups,
make the above possibility unlikely.
The relatively slow rise time for AMPAR-mediated responses (cf. Geiger
et al., 1997; Zhou and Hablitz, 1997) observed in our experiments is
probably attributable to the remote electrotonic location of the
synapses on distal dendritic spines. By contrast, spontaneous EPSCs
were routinely obtained with rise times of <1 msec, indicating that
the clamp-response time was adequate to obtain such measurements
(Kumar and Huguenard, 2001). The rise times observed for neocortical
layer 5 pyramidal neurons in this study are comparable with those
obtained for CA1 synapses in the hippocampus (Hestrin et al., 1990).
Although the precise locus of callosal input onto pyramidal cells in
rats remains unknown, in rabbits it is restricted exclusively to the
oblique branches of the apical dendrites in the adult animals,
suggesting a distinct anatomical locus for the bulk of the callosal
input onto these neurons (Globus and Scheibel, 1967). These synapses
were localized to the deep layers 3 and 4 ~200 µm from the cell
soma, which would correspond to a passive attenuation factor of ~20%
(Häusser and Roth, 1997). Using a simulation approach, we find
that given the equivalent series resistances and holding currents
observed in young and old neurons (Fig. 3F), changes
in neuronal morphology or leak conductance would not contribute to the
observed differences in rectification (J. R. Huguenard and S. S. Kumar, unpublished observations), indicating that the developmental
alterations in EPSC properties result predominantly from changes in
synaptic AMPARs.
In the local perfusion experiments used for assessing
Ca2+ permeability (Fig. 5), we found that
it was necessary to increase stimulus intensity to restore synaptic
responses when
[Ca2+]o was
elevated (Otis et al., 1995). The higher stimulus intensity could
potentially result in activation or recruitment of a different set of
synapses or both. This seems unlikely, given the comparable waveforms
and kinetics of EPSCs evoked under these conditions (Fig.
5B). Furthermore, experiments involving dual stimulation (intracortical and callosal; Figs. 1F,
4B) suggest that AMPAR-mediated synapses on pyramidal
neurons have similar properties. Thus, increasing stimulus intensity
most likely evokes a response that is dependent on the same compliment
of glutamate receptors as before (note that NBQX blocks the EPSCs in
elevated Ca2+; Fig. 5B).
Interpreting anatomical results
Despite the fact that anatomical experiments provide only an
indirect measure of synaptic GluR2 expression in the cells of interest,
they do show that the pyramidal neurons sampled in our study change
their overall phenotype from one of relatively low expression at times
before ~P16 to one of high expression later in development. These
results are consistent with the developmental profile of GluR2 gene
expression in cortical tissue (Pellegrini-Giampietro et al., 1992).
Differences in GluR2 expression between the age groups are manifested
not only in terms of absolute levels within respective cells but also
relative to other subunits, GluR1 and GluR4, that are coexpressed with
GluR2. The fact that GluR2/1 and GluR2/4 ratio estimates in P21 neurons
are larger by ~30 and 14%, respectively, compared with P12 neurons,
suggests that developmental increases in GluR2 expression are not
merely attributable to increases in the total number of AMPARs
expressed by these neurons but are also attributable to alterations in
receptor stoichiometry.
Heterogeneity of AMPARs within single neurons
The direct demonstration that synaptic AMPARs from the younger but
not the older age group are permeable to
Ca2+ strongly supports the hypothesis of a
developmentally regulated change in the subunit composition of these
receptors with respect to the GluR2 subunit. Exceptions most likely
include extrasynaptic AMPARs, located on the somas of neocortical
pyramidal neurons, which might differ from their counterparts at the
synapse in terms of their function and respective subunit compositions
(Lerma et al., 1994; Carder, 1997; Yin et al., 1999). Indeed,
application of glutamate to outside-out patches from pyramidal cell
somas in P16 or younger neurons shifted the
Erev of AMPAR-mediated responses from
~0 mV in 1.8 mM
Ca2+ to 62 mV in 100 mM Ca2+,
corresponding to a
PCa/PNa
ratio of 0.04. Together with the current results, this suggests a
significantly lower Ca2+ permeability for
somatic as opposed to synaptic AMPARs (Kumar and Huguenard, 2001). The
finding of input-specific AMPAR responses in hippocampal interneurons
(Toth and McBain, 1998) provides further support for inhomogeneous
AMPAR distribution in the neuronal somatodendritic membranes.
The GluR2 subunit and neuronal development
Previous studies have suggested that developmental regulation of
Ca2+-permeable AMPARs, possibly through
regulation of GluR2 expression, occurs in a variety of systems. For
example, in spinal interneurons of Xenopus embryos, there is
a transient occurrence of Ca2+-permeable
AMPARs early in development (Rohrbough and Spitzer, 1999), as would be
expected for GluR2-deficient receptors. In avian cochlear nuclei, there
is an increase in sensitivity to intracellular spermine that occurs
between embryonic day 11 (E11) and E18 (Lawrence and Trussell, 2000),
consistent with a downregulation of GluR2 during this period.
Functional GluR2 changes in synaptic receptors have not been reported
previously, although colocalization studies of synaptophysin and GluR2
immunoreactivities in cultured hippocampal neurons suggest that the
relative abundance of GluR2 at synaptic AMPARs increases with
development (Pickard et al., 2000). Yuste et al. (1999) have also
reported, using two-photon imaging with
Ca2+ indicator dyes, that a minor
subpopulation of dendritic spines on hippocampal CA1 pyramidal neurons
show an APV-resistant Ca2+ influx with
synaptic stimulation in P20 rats. These studies, including our direct
demonstration of altered Ca2+ permeability
in synaptic AMPARs, suggest that regulation of
Ca2+ permeability in AMPARs via
alterations in GluR2 content may be a common feature of neuronal development.
Functional significance
Alteration of the synaptic AMPAR subunit composition represents a
novel Ca2+-dependent mechanism for the
control of neocortical excitability and development. The switch in
GluR2 expression and the resulting change in the permeability of
Ca2+ through these receptors (Geiger et
al., 1995; Jonas and Burnashev, 1995; Gu et al., 1996; Washburn et al.,
1997; Yin et al., 1999) are likely to have important functional
implications relating developmental (Rohrbough and Spitzer, 1999;
Lawrence and Trussell, 2000) and activity-dependent forms of synaptic
plasticity (Mahanty and Sah, 1998; Liu and Cull-Candy, 2000) in the
neocortex. Furthermore, the early low expression of GluR2 might
underlie the increased seizure susceptibility of the immature brain
(Schwartzkroin and Prince, 1980; Moshe et al., 1983; Sensi et al.,
1999). In a recent study, Sanchez et al. (2001) showed that
hypoxia-induced seizures in neonatal rats (P10-P12) are linked with
maturational and seizure-induced changes in AMPAR composition and
function, particularly in relation to the GluR2 subunit. Their results
indicated further that seizures induce an increased expression of
Ca2+-permeable AMPARs and an increased
capacity for AMPAR-mediated epileptogenesis. The AMPAR switch described
in this study occurs approximately midway during the period of maximum
synaptogenesis in rats (P11-P20; Sutor and Luhmann, 1995) and results
in changes in the functional properties of AMPARs that depend on the
presence or absence of GluR2. Failure to switch the subunit composition of these receptors to incorporate GluR2 at this juncture might have
deleterious consequences relating to neocortical excitability (Pellegrini-Giampietro et al., 1997; Feldmeyer et al., 1999).
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FOOTNOTES |
Received July 25, 2001; revised Jan. 28, 2002; accepted Jan. 29, 2002.
This work was supported by an American Epilepsy Society research
training fellowship (S.S.K.) and by grants from the National Institutes
of Health. We thank C. Lin for assistance with immunohistochemistry and
R. C. Malenka, R. W. Tsien, S. Hestrin, and D. Porcello for critiquing an early version of this manuscript.
Correspondence should be addressed to Dr. John R. Huguenard at the
above address. E-mail: John.Huguenard{at}Stanford.edu.
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A. Bacci, J. R. Huguenard, and D. A. Prince
Differential modulation of synaptic transmission by neuropeptide Y in rat neocortical neurons
PNAS,
December 24, 2002;
99(26):
17125 - 17130.
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
