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Volume 17, Number 13,
Issue of July 1, 1997
pp. 5119-5128
Copyright ©1997 Society for Neuroscience
Slow Kinetics of Miniature IPSCs during Early Postnatal
Development in Granule Cells of the Dentate Gyrus
Greg S. Hollrigel and
Ivan Soltesz
Department of Anatomy and Neurobiology, University of California,
Irvine, California 92697
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Whole-cell patch-clamp recordings were used to investigate the
properties of GABAA receptor-mediated postsynaptic currents during development in dentate gyrus granule cells from neonatal [postnatal day 0 (P0)] to adult rats in brain slices. The frequency of miniature IPSCs (mIPSCs) was low at birth and increased
progressively with age. The mIPSCs of all ages could be satisfactorily
fitted with the sum of a single exponential rise and single exponential decay. From P0 to P14, both the rise time and the decay time constants were significantly longer than in the adult. The mIPSC rise and decay
kinetics did not change during the first 2 postnatal weeks, but during
the third week the kinetics sped up and by P21 attained adult values.
In contrast, the amplitude of the mIPSCs did not change during
development. The synaptic GABAA receptors in immature and
adult cells showed differential sensitivity to modulators. The
subunit-specific benzodiazepine agonist zolpidem increased the decay
time constant of the IPSCs of immature granule cells with a reduced
potency compared with the adult. Furthermore, zinc decreased the
amplitude and decay time constant of mIPSCs from developing granule
cells, whereas it had no effect on mIPSCs in adult neurons.
The results reveal for the first time that until the end of the second
postnatal week the synaptic GABAA receptor-mediated currents in dentate granule cells display slower rise and decay kinetics but similar amplitudes compared with adult, resulting in a net
decrease in synaptic charge transfer during development.
Key words:
GABAA receptor;
development;
dentate gyrus;
inhibition;
subunit;
zolpidem;
zinc
INTRODUCTION
The GABAergic innervation of dentate granule
cells plays a central role in regulating the information flow between
the entorhinal cortex and the hippocampus (Buzsáki et al., 1983 ).
At least five types of GABAergic neurons supply inhibitory terminals to
adult dentate granule cells, specifically innervating spatially
segregated parts of the neuron such as the axon initial segment, soma,
and proximal and distal dendrites (Halasy and Somogyi, 1993; Han et al., 1993). The high specificity of target selection by dentate interneurons has important functional consequences (Cobb et al., 1995;
Soltesz et al., 1995; Miles et al., 1996). Although there has been a
considerable increase in our understanding of the operational principles of inhibitory microcircuits in the adult (Freund and Buzsáki, 1996), little is known about the synaptic construction of the dentate inhibitory system during development.
There are several clues which indicate that the organization of
the developing dentate gyrus is fundamentally different from the adult.
First, dentate GABAergic cells are born prenatally, whereas 80% of the
granule cells are generated after birth (Schlessinger et al., 1975,
1978; Bayer, 1980; Soriano et al., 1989). Second, early in life, most
GABAergic functions take place via GABAA receptors, because
postsynaptic GABAB responses develop relatively late
(Fukuda et al., 1993, Gaiarsa et al., 1995). Third, in contrast to the adult hippocampus, in which major roles for GABA are the control of
excitability, the generation of 40 Hz oscillations, and the precision
timing of action potentials (Buzsáki et al., 1983; Soltesz and
Deschênes, 1993; Whittington et al., 1995), in immature neurons
GABA has several developmental roles. For example, GABA influences the
outgrowth of neuronal processes in picomolar concentrations (Behar et
al., 1996), modulates DNA synthesis (LoTurco et al., 1995), and
regulates neuronal phenotype (Marty et al., 1996). These developmental
actions of GABA are likely to be associated with the fact that
GABAA activation early in life leads to depolarizations and
the opening of voltage-gated Ca2+ channels,
resulting in various developmental changes via increases in
intracellular [Ca2+] (Ben-Ari et al., 1989;
Cherubini et al., 1991; Yuste and Katz, 1991; Gaiarsa et al., 1995;
Rohrbough and Spitzer, 1996). Fourth, GABAA receptor
subunit expression undergoes a prominent switch during postnatal
development (Laurie et al., 1992; Fritschy et al., 1994). The
functional consequences of the developmental changes in the subunit
composition of GABAA receptors in cortical structures are
not well understood.
This study has been undertaken to answer the following questions.
(1) Can spontaneous GABAA IPSCs be revealed in immature dentate granule cells? (2) If yes, given the pivotal importance of the
amplitude and kinetics of the synaptic events in regulating the timing
of neuronal signals, what differences do the GABAergic events show in
immature and adult granule cells? (3) Do granule cells at different
maturational stages display distinct GABAA receptor-mediated responses? (4) Do synaptic GABAA
receptors respond differently to subunit-specific modulators in the
developing versus adult dentate gyrus? The answers to these questions
are important because they advance our knowledge of how
GABAA signals operate in the developing cortico-limbic
system.
MATERIALS AND METHODS
Slice preparation. Brain slices were prepared similar
to what has been described previously (Otis and Mody, 1992; Staley et al., 1992). Neonatal Wistar rats (P0-P5) were anesthetized by hypothermia, P6-P14 rats were anesthetized with halothane, and older
rats (P21-adult) were anesthetized with sodium pentobarbital (75 mg/kg, i.p.). Anesthetized rats were decapitated, and the brains were
removed and cooled in 4°C oxygenated (95% O2/5%
CO2) artificial cerebral spinal fluid (ACSF)
composed of (in mM): 126 NaCl, 2.5 KCl, 26 NaHCO3, 2 CaCl2, 2 MgCl2, 1.25 NaH2PO4,
and 10 glucose. Horizontal brain slices (Staley et al., 1992) (450 µm) were prepared with a vibratome tissue sectioner (Lancer Series 1000). The brain slices were sagittally bisected into two hemispheric components and incubated submerged in 32°C ACSF for 1 hr.
Electrophysiology. Individual slices were transferred to a
submersion-type recording chamber (Soltesz et al., 1995; Hollrigel et
al., 1996) perfused with ACSF containing 10 µM
2-amino-5-phosphovaleric acid (APV) and 5 µM
6-cyano-7-nitroquinoxaline-2,3-dione (CNQX); in some experiments, the
perfusion solution included 1 µM tetrodotoxin (TTX). The
brain slices rested on filter paper and were stabilized with platinum
wire weights. The tissue was superfused continuously with humidified
95%O2/5%CO2, and the
temperature of the perfusion solution was maintained at 36°C. All
salts were obtained from Fluka (Buchs, Switzerland). APV and CNQX were
purchased from Tocris, and TTX was obtained from Calbiochem (LaJolla,
CA). Drugs were applied via the perfusion system. Zolpidem (10 mM stock; courtesy of Dr. G. White, Neurogen Corp.) and
zinc solutions were prepared daily.
Patch pipettes were pulled from borosilicate (KG-33) glass capillary
tubing (1.5 mm outer diameter; Garner Glass) with a Narishige PP-83
two-stage electrode puller. Pipette solutions consisted of (in
mM): 140 CsCl, 2 MgCl2, and 10 HEPES,
and in some experiments, 3 QX-314, 0.2 EGTA, and/or biocytin (0.3%).
"Blind" whole cell recordings were obtained as described previously
(Blanton et al., 1989; Staley et al., 1992). Recordings were obtained
with an Axopatch-200A amplifier (Axon Instruments, Foster City, CA) and
digitized at 88 kHz (Neurocorder, NeuroData) before being stored in
pulse code modulation form on videotape. The series resistance was
monitored throughout the recordings, and the data were rejected if it
increased beyond 15 M .
Analysis. Recordings were filtered at 3 kHz before
digitization at 20 kHz by a personal computer for analysis using
Strathclyde Electrophysiology Software (courtesy of Dr. J. Dempster)
and Synapse software (courtesy of Dr. Y. De Koninck). Detection of
individual IPSCs was performed with a software trigger described
previously (Otis and Mody, 1992; Soltesz et al., 1995). All of the
detected events were analyzed, and any noise that spuriously met
trigger specifications was rejected. A least-squares Simplex-based
algorithm was used to fit the ensemble average with the sum of two (one rising and one decaying) or three (one rising and two decaying) exponentials:
where I(t) is the mIPSC as a function of
time (t); A1 + A2 = A are constants; and
 r, D1, and
D2 are the rise, fast decay, and slow decay time
constants, respectively. For single exponential decays,
A1 was equal to 0. As described before (Soltesz
and Mody, 1995; Hollrigel et al., 1996), to evaluate the improvement of the fit by adding a second exponential decay component, an F-test was
used to assess the improvement in the value of the ratio
(SSE1  SSE2)/SSE2
("%SSE improvement"), where SSE1
and SSE2 are the sum of squared errors of the
fits with one or two exponential decays, respectively. When the %SSE
improvement is not significant (as is the case in granule cells of all
ages; see below), it indicates that the mIPSC from such a cell is
described satisfactorily by the use of a single exponential rise and a
single exponential decay function, and the r and the
D2 from this fit can be used (by contrast, when the
%SSE improvement is significant, e.g., after dendrotomy performed in
control medium, the r, D1,
and D2 are all considered in the subsequent analysis)
(Soltesz and Mody, 1995). Statistical analyses were performed with SPSS
for Windows or SigmaPlot, with a level of significance of
p  0.05. Data are presented as mean ± SE
(n is number of cells).
Histology. To visualize recorded cells filled with biocytin,
slices were processed as whole mounts (Claiborne et al., 1986). Briefly, after allowing diffusion of the tracer for 20-60 min in the
recording chamber, the slice was fixed in a solution of 4%
paraformaldehyde, 2.5% glutaraldehyde, and 0.2% picric acid overnight
at 4°C. The sections were washed thoroughly in 0.1 M phosphate buffer (PB) and subsequently cryoprotected in 10% and 20%
sucrose. The tissue was then frozen in liquid nitrogen and thawed.
Slices were incubated in 1% H2O2 for 30 min
and washed extensively. The tissue was incubated in an ABC solution
(Vector, Burlingame, CA) overnight at 4°C and washed thoroughly
before it was reacted with 3,3 -diaminobenzidine tetrahydrochloride
(concentration, 0.015%) and 0.006% H2O2. The
reacted slices were cleared in an ascending series of glycerol
(Claiborne et al., 1986) and coverslipped before the cells were
reconstructed with a camera lucida.
RESULTS
GABAA receptor-mediated miniature events are present at
all postnatal ages and their frequency increases during development in
granule cells of the dentate gyrus
GABA-mediated postsynaptic currents were recorded from dentate
granule cells voltage-clamped at 60mV with
Cl -filled pipettes
([Cl]in = [Cl]out) (Otis and Mody,
1992) (throughout the experiments reported in this paper, to
standardize our recording site, we restricted our recordings to the
dorsal blade and the adjacent half of the crest of the granule cell
layer). The inward currents (Fig. 1) reversed at
0.5 ± 2.1 mV (predicted ECl = 0mV) and
were reversibly blocked by the GABAA receptor antagonist
bicuculline (20 µM; n = 3; data not
shown) (the developmental changes in the relationship between
ECl and the resting membrane potential, input
resistance, and neuronal rhythms will be examined in a separate study).
In the presence of APV, CNQX, and TTX, mIPSCs were detected in 86.0% (49/57) of the cells from P0-P4 rats. The frequency of the mIPSCs increased with age (Fig. 1) from 0.8 ± 0.2 Hz (P0-P4;
n = 13) to the adult value of 11.0 ± 2.1 Hz
(n = 6). The low proportion of cells without miniature
synaptic events from P0-P4 rats suggests that most granule cells
receive GABAergic synaptic innervation shortly after becoming
postmitotic, presumably from interneurons already present in the
dentate network at birth (Amaral and Kurz, 1985; Lubbers et al., 1985;
Dupuy and Houser, 1996). The developmental increase in the frequency of
miniature events most likely reflects an increase in the number of
GABAergic synaptic release sites related to the increased innervation
of granule cells by axons of interneurons (Lubbers and Frotscher, 1988;
Seress et al., 1989; Seress and Ribak, 1990; Dupuy and Houser, 1996).
In contrast to cerebellar granule cells (Tia et al., 1996), bicuculline
did not decrease the baseline "noise," indicating that there is no
significant activation of GABAA receptors by ambient GABA.
In addition, there was no significant increase in the baseline
"noise" during development (e.g., Fig. 1), in contrast to what has
been observed in cerebellar granule cells (Tia et al., 1996).
Fig. 1.
mIPSC frequency increases with age in dentate
granule cells. Top traces are representative recordings of mIPSCs
recorded in voltage-clamp at 60mV with CsCl-filled pipettes. The
GABA-mediated Cl currents reversed at 0.5 ± 2.1 mV and were blocked by 20 µM bicuculline (not
shown). The bar graph is the summary of the frequency of
mIPSCs as a function of age. The frequency continued to increase throughout the ages examined. P0-P4: 0.8 ± 0.2 Hz; P5-P9:
1.7 ± 0.5 Hz; P10-P14: 2.3 ± 0.5 Hz; P21: 6.7 ± 0.6 Hz; adult: 11.0 ± 2.1 Hz. The number of cells is
indicated in parentheses.
[View Larger Version of this Image (25K GIF file)]
mIPSCs in immature cells display slower kinetics but similar
amplitudes compared with adult
Figure 2A is an example of
averaged mIPSCs from P0-P4 neurons (489 mIPSCs, n = 7)
and adult neurons (478 mIPSCs, n = 2) with similarly
low series resistances (<8 M). mIPSCs recorded from developing
granule cells of the dentate gyrus, similar to the mIPSCs from adult
dentate granule cells (Otis and Mody, 1992; Soltesz and Mody, 1995),
could be satisfactorily fit with the sum of a single exponential rise
and single exponential decay (i.e., the "SSE improvement" was not
significant; see Materials and Methods) (Soltesz and Mody, 1995;
Hollrigel et al., 1996) (Figs. 2A, 4). Analysis of
the mIPSCs recorded from P0-P4 granule cells revealed that the
10-90% rise times (Fig. 2A,C) (or rise time
constants, Fig. 3A) and the decay time constants
(Fig. 2D) were significantly larger than the values
obtained from adult neurons. Importantly, although the rise times and
the decay time constants of the mIPSCs from P0-P4 neurons were
significantly different from the adult, the mIPSC amplitudes were
identical in P0-P4 and adult neurons (Fig.
2A,B).
Fig. 2.
The kinetics of mIPSCs is slower in P0-P4 granule
cells compared with adult granule cells, and kinetics of mIPSCs from
P5-P9 neurons remains slower than that of adult neurons.
A, Averages of 489 mIPSCs (P0-P4) and 478 mIPSCs
(adult) recorded at 60mV. Both the rise and decay are qualitatively
slower than the adult current. The mIPSCs in the adult as well as in
the young cells were fit by the sum of a single exponential rise and
single exponential decay. The values for the equations were as follows:
adult, A = 92.5 pA; r = 0.15 msec;
D = 4.3 msec; young: A = 99.2 pA; r = 0.36 msec; D = 9.5 msec. B, C,
D, Cumulative probability plots of the amplitude, rise time
(10-90%), and single exponential decay time of the mIPSCs in
A. The median amplitudes were P0-P4, 74.41 pA; P5-P9,
69.9 pA; adult: 76.37 pA. The median rise times were P0-P4, 0.91 msec;
P5-P9, 1.03 msec; adult: 0.29 msec. The median decay time constants
were P0-P4, 9.2 msec; P5-P9, 7.7 msec; adult, 4.5 msec. Significant
differences of the distributions were found for the rise times and
decay time constants for the P0-P4/P5-P9 versus adult groups, whereas
there was no significant difference between P0-P4 and P5-P9
(Kolmogorov-Smirnov test).
[View Larger Version of this Image (32K GIF file)]
Fig. 4.
GABAA receptor-mediated synaptic
currents of granule cells at different stages of development have
similar kinetics. A, B, Two examples of granule cells
recorded and stained with biocytin. The dashed lines
indicate the borders of the granule cell layer. Note that both cells
were located within the granule cell layer, each had an axon projecting
through the hilus, and the majority of the dendrites were oriented
toward the molecular layer. C, D, The averages of the
IPSCs recorded from A and B,
respectively. Open circles are the raw data points; the
solid line is the best-fit function describing the
currents. Each cell, despite different stages of maturation, had
similar IPSC kinetics. The values for the equations were
(C) A = 194.3 pA;
r = 0.43 msec; D = 11.1 msec;
(D) A = 243.3 pA;
r = 0.37 msec; D = 13.5 msec. Note that
the currents were accurately described by the sum of a single exponential rise and a single exponential decay.
[View Larger Version of this Image (14K GIF file)]
Fig. 3.
mIPSC kinetics is developmentally regulated.
A-C, Summary data of the rise time constants, decay
time constants, and amplitudes of the mIPSCs as a function of age. Bars
of the same color are not statistically different (t
test). Both the rise time constants and decay time constants
significantly decreased at P21 and were not different from adult
values. The amplitude of the mIPSCs did not change with age.
D, Bar graph of the synaptic charge transfer (measured
as the area under the best-fit curve describing the IPSCs) versus age.
Consistent with the developmental change in kinetics, the synaptic
charge transfer was larger in young neurons (242.3 ± 22.2% of
the adult) and decreased to adult values by P21 (100.5 ± 3.0%).
Numbers in parentheses are the number of
cells.
[View Larger Version of this Image (36K GIF file)]
Similar to P0-P4 pups, the 10-90% rise times and decay time
constants of the mIPSCs of dentate granule cells from P5-P9 rats remained significantly slower compared with adult granule cells (Fig.
2C,D) (n = 3), with the amplitudes being
similar (Fig. 2B). The significance of these findings
in P5-P9 rats is that basket cells are known to establish synapses on
the somata of granule cells by P5 (Seress et al., 1989; Seress and
Ribak, 1990). The presence of somatic synapses by P5-P8, the similar
mIPSC amplitude, and the fact that there was no evidence of correlation
in the rise time constant versus amplitude plots
(r2 = 0.12) argue against the possibility
that electrotonic filtering would underlie the observed kinetic
differences (see Discussion). Indeed, the slower kinetics persisted in
neurons recorded from animals younger than P15 (Fig.
3A-C). Figure 3, A and
B, indicates that the rise time constants and decay time
constants of the mIPSCs from animals younger than P15 were not
different (rise time constant: P0-P4 = 0.41 ± 0.05 msec,
n = 13; P10-P14 = 0.50 ± 0.05 msec, n = 8; decay time constant: P0-P4 = 9.6 ± 0.7 msec, n = 13; P10-P14 = 8.3 ± 0.5 msec,
n = 8). Both the rise time and decay time constants, however, decreased to the adult values by P21 (rise time constant: 0.20 ± 0.01 msec; decay time constant: 5.2 ± 0.4 msec;
n = 4). The lack of a change in the amplitude of the
mIPSCs during development in dentate granule cells is shown in Figure
3C (P0-P4 = 74.0 ± 3.8 pA; adult = 72.4 ± 4.2 pA). It is interesting to note that the distributions
of the rise and decay time constants and of the amplitude of the mIPSCs
recorded from any single cell from all age groups showed the skewed
distribution well described in the adult (e.g., Soltesz et al., 1995),
i.e., there was no evidence of two distinct populations of mIPSCs in
any given cell. The slower decay kinetics and the similar amplitude in
the young granule cells resulted in a larger synaptic charge transfer
of the synaptic GABAA receptors compared with adult (Fig.
3D) (P0-P4 = 242.3 ± 22.2% of the adult;
P21 = 100.5 ± 3.0% of the adult). These data indicate that
for the first 2 weeks after birth, the kinetics of the GABA-mediated
synaptic currents are slow and the synaptic charge transfer is
relatively larger, and that during the third postnatal week the
currents become faster and the charge transfer reaches its adult value
by P21.
The kinetics of IPSCs in granule cells correlates with the age of
the animal and not with the maturational stage of the neuron
In the experiments reported above, we noted that there was
remarkably little variability between the mIPSC parameters in cells recorded from developing animals belonging to a particular age group
(e.g., the SEM of the frequency in Fig. 1 is actually the largest in
the adult group). Similarly, there was no significant difference
between the kinetic properties of mIPSCs between the age groups P0-P4,
P5-P9, and P10-P14. These observations were unexpected, because
granule cells continue to be generated throughout the early postnatal
period (and, albeit at a slower rate, even in the adult) (Kuhn et al.,
1996), which means that granule cells in the early postnatal dentate
gyrus can be at significantly different stages of maturation (see
below). If the IPSC kinetics was determined by the neuronal
maturational stage, we would have expected a large variability between
the mIPSC characteristics of granule cells (i.e., some showing clearly
immature-type kinetics, others adult-like kinetics). This is clearly
not what was found, however, because before P14 virtually all granule
cells had slow rise and decay kinetics, distinct from the kinetics
observable in cells recorded after P21. To examine the relationship
between the developmental stage of the cell and the properties of
IPSCs, we performed experiments using biocytin injections and camera
lucida reconstructions of cells recorded in the granule cell layer
(n = 15). As illustrated in Figure 4,
neurons at different maturational stages, evidenced by the differential
complexity of the dendritic and axonal trees, clearly showed very
similar kinetic parameters of IPSCs [note that all of the neurons were
filled for >20 min, which is sufficient to completely fill the
dendritic tree of even the larger, fully developed adult granule cells
(Soltesz et al., 1995)]. Also, all of the processes of the
immature-looking P2 cell in Figure 4 ended within the slice and and not
on the cut surface of the slice; similar morphologies of immature
granule cells have been demonstrated previously (e.g., Cowan et al.,
1980; Lubbers and Frotscher, 1988; Rihn and Claiborne, 1990; Liu et
al., 1996). We classified the electrophysiologically recorded,
morphologically identified granule cells in the following manner:
simple cells, granule cells with 0-6 dendritic branch points;
intermediate cells, granule cells with 7-13 dendritic branchpoints;
and complex cells, granule cells with >13 dendritic branch points. The
time constant data for these three groups were similar (simple cells:
rise time constant, 0.43 ± 0.06 msec; decay time constant,
10.6 ± 0.8 msec, n = 4; intermediate cells: rise
time constant, 0.53 ± 0.09 msec; decay time constant, 9.1 ± 0.7 msec, n = 3; complex cells: rise time constant,
0.47 ± 0.12 msec; decay time constant, 10.0 ± 1.8 msec,
n = 3). These findings indicate that it is the
postnatal age of the animals (i.e., whether the animal is <P15 or
>P21) that determines the kinetics of the mIPSCs and not the neuronal
developmental stage. The importance of the third postnatal week in this
respect may be related to the fact that the eyes of the rat pups open
at approximately P14, and the animals start to move around and
extensively explore the environment at the beginning of the third
postnatal week, likely resulting in a relatively sudden increase in
neuronal activity coming from the cortical areas to the dentate gyrus
and the hippocampus.
A related issue concerns the identity of the recorded cells. Our
experiments with biocytin filling and reconstructions showed that 12 of
the 15 neurons filled in P0-P6 animals clearly met our strict criteria
for granule cells: (1) the cell body was located within the granule
cell layer; (2) the cell had an axon coursing through the hilus toward
the CA3 region (i.e., along the mossy fiber pathway); and (3) the
majority of the dendrites were oriented toward the molecular layer and
did not curve back into the granule cell layer. Furthermore, the
remaining three unclassified cells (which may include somewhat atypical
granule cells as well as interneurons) showed no significant
differences in their mIPSC kinetics with respect to those neurons,
which met our criteria for granule cells. Taken together, these results
indicate that granule cells in the dentate gyrus from <P15 show
similarly slow kinetics, regardless of the maturational stage.
Synaptic GABAA receptors in developing granule cells
show differential sensitivity to subunitspecific modulators
The subunit composition of GABAA receptors influences
the main conductance state, kinetics, and sensitivity to modulators (Sigel et al., 1990; Verdoorn et al., 1990; Macdonald and Olsen, 1994).
In adult granule cells, in situ hybridization and
immunocytochemical studies have shown the expression of 10 different
GABAA receptor subunits, including the  1, 2, 4,
5,  1, 2, 3,  1, 2, and  1 subtypes (Schoch et al.,
1985; Richards et al., 1987; Houser et al., 1988; Benke et al., 1991;
Zimprich et al., 1991; Laurie et al., 1992; Persohn et al., 1992;
Turner et al., 1993; Gao and Fritschy, 1994; Gutierrez et al., 1994;
Nusser et al., 1995). It is the 1, 2, and 1 subunits that
undergo the most prominent developmental changes in the dentate gyrus
of postnatal rats (Killisch et al., 1991; Laurie et al., 1992; Poulter
et al., 1992, 1993; Fritschy et al., 1994). Unlike in the hippocampus,
5 does not seem to change in the dentate gyrus (Killisch et al.,
1991; Poulter et al., 1992), and these subunits have been shown to
alter the time course of postsynaptic GABA signals, including the
modulation of burst characteristics, activation, and desensitization
rates (Angelotti and Macdonald, 1993; Saxena and Macdonald, 1994;
Gingrich et al., 1995; Dominguez-Perrot et al., 1996). In the final
series of experiments, we compared the sensitivity of the synaptic
GABAA receptors in immature versus adult dentate granule
cells with the presently available subunit-specific modulators zolpidem
and zinc, whose modulatory actions are influenced by precisely those subunits that undergo developmental change in their levels of expression in the dentate gyrus, i.e., the , 2, and 1 subunits (Draguhn et al., 1990; Pritchett and Seeburg, 1990; Puia et al., 1991;
Davies et al., 1993; Mertens et al., 1993; Rovira and Ben-Ari, 1993;
Macdonald and Olsen, 1994; Saxena and Macdonald, 1994; White and
Gurley, 1995; Kapur and Macdonald, 1996). Because of the very low mIPSC
frequency in the immature cells, and the considerable time to achieve
full potentiation of the decay time constant by zolpidem in these thick
slices, these experiments were performed on slices incubated in the
respective drug for 40-90 min [the percentage zolpidem potentiation
of the decay time constant seen after switching from control to the
drug-containing solution in the same adult cells (n = 3) was not statistically different from that observed in cells obtained
from slices incubated in zolpidem for 40-90 min (see below), i.e.,
once full potentiation is achieved, it remains stable; a similar
approach has been used previously with propofol and thiopental, two
drugs that also need a relatively long time for full effect in slices
(Hollrigel et al., 1996)].
The benzodiazepine zolpidem has a higher affinity for GABAA
receptors with 1 subunit compared with receptors with 5 subunit (Pritchett and Seeburg, 1990; Puia et al., 1991; Mertens et al., 1993),
and it is known to prolong the decay of mIPSCs in adult dentate granule
cells without affecting mIPSC amplitudes (Mody et al., 1994; Soltesz
and Mody, 1994). Zolpidem at a concentration of 0.05 µM
did not change the decay time constant in either the young
(n = 6) or adult (n = 4) IPSCs;
however, the difference in potency was clearly evident at 0.5 µM (Fig. 5). In the adult (n = 4), 0.5 µM zolpidem increased the
decay time constant by 80.5 ± 8.6%, whereas in P0-P4 animals
(n = 5) it increased the decay time constant by only
27.3 ± 9.0%. The difference in potentiation was reduced when a
high concentration of zolpidem (5.0 µM) was used
(increase of decay time constant: P0-P4 = 82.0 ± 30.3%,
n = 3; adult = 97.2 ± 5.1%,
n = 4).
Fig. 5.
Synaptic GABAA receptors of young
granule cells are less sensitive to modulation by zolpidem. In both the
young and adult granule cells, 0.05 µM zolpidem did not
significantly increase the decay time constant of the IPSCs (P0-P4,
8.8 ± 8.5% increase; adult, 9.8 ± 5.9% increase);
however, 0.5 µM zolpidem increased the decay time
constant of P0-P4 IPSCs by 27.3 ± 9.0% and of adult IPSCs by
80.5 ± 8.6%. The difference in the relative increase caused by
0.5 µM zolpidem was significant between the P0-P4 values and adult values. Zolpidem (5.0 µM) increased P0-P4 IPSC
decay times by 82.0 ± 30.3% and adult IPSC decay times by
97.2 ± 5.1%. These effects were not significantly different
(t test). Number of cells indicated
within the bars.
[View Larger Version of this Image (16K GIF file)]
Next, the effect of zinc (Westbrook and Mayer, 1987; Harrison and
Gibbons, 1994; Smart et al., 1994; Buhl et al., 1996), whose blocking
actions on the GABAA receptor is influenced by the , 2, and 1 subunits (Draguhn et al., 1990; Macdonald and Olsen, 1994; White and Gurley, 1995), was tested in developing versus adult
granule cells. Similar to previously published results (Buhl et al.,
1996), zinc did not alter the mIPSCs in adult dentate granule cells
(Fig. 6) (n = 4). By contrast, in
granule cells from P0-P4 rats, zinc (300 µM)
significantly decreased the amplitude (control, 74.0 ± 3.8 pA;
zinc, 54.0 ± 3.9 pA; a 27.0% decrease) and the decay time
constant (control, 9.6 ± 0.7 msec; zinc, 6.9 ± 0.8 msec; a
28.1% decrease) of the mIPSCs (n = 7). Zinc did not
change the rise time constant of the mIPSCs (control, 0.41 ± 0.05 msec; zinc, 0.41 ± 0.04 msec), indicating that the effect on the
decay time constant was not attributable to an improved space-clamp
resulting from the zinc-induced decrease in synaptic GABAA
current amplitude. A lower concentration of zinc (30 µM) also decreased both the amplitude (by 18.1 ± 8.9%;
n = 5) and decay time constant (by 10.4 ± 7.1%;
n = 5) in developing granule cells, albeit the
difference with respect to control did not reach a statistically
significant level. The smaller zolpidem potency and the larger effects
of zinc on the mIPSCs in developing versus adult granule cells are
likely to be related to the lower levels of expression of 1, 2,
and 1 subunits (Draguhn et al., 1990; Killisch et al., 1991; Poulter
et al., 1992; Davies et al., 1993; Rovira and Ben-Ari, 1993; Fritschy
et al., 1994; Macdonald and Olsen, 1994; White and Gurley, 1995). Thus,
these pharmacological data indicate that age-dependent alterations take
place in synaptic GABAA receptor properties in dentate
granule cells.
Fig. 6.
Zinc inhibits mIPSCs of young granule cells.
A-C, Bar graphs comparing the effects of
ZnCl2 (300 µM) on mIPSC amplitude, decay time
constant, and rise time constant. Zinc significantly decreased the
amplitude (control, 74.0 ± 3.8 pA; zinc, 54.0 ± 3.9 pA) and decay time constant (control, 9.6 ± 0.7 msec; zinc, 6.9 ± 0.8 msec) of P0-P4 mIPSCs. Zinc did not change the rise time constant of P0-P4 mIPSCs (control, 0.41 ± 0.05 msec; zinc, 0.41 ± 0.04 msec). In addition, zinc did not change the parameters of adult mIPSCs: amplitude (control, 72.4 ± 4.2 pA; zinc, 66.6 ± 8.9 pA), decay time constant (control, 4.5 ± 0.2 msec; zinc, 4.2 ± 0.3 msec), rise time constant (control, 0.19 ± 0.02 msec;
zinc, 0.18 ± 0.00 msec). Number of cells indicated
within the bars.
[View Larger Version of this Image (16K GIF file)]
DISCUSSION
The main findings of this study are that (1) functional GABAergic
synaptic contacts are established on dentate granule cells immediately
after birth; (2) the frequency of the mIPSCs increases with age; (3)
the mIPSCs from immature granule cells as well as in the adult can be
satisfactorily fitted with the sum of a single exponential rise and
single exponential decay; (4) mIPSCs are slower in developing animals
but are similar in amplitude compared with the adult, resulting in a
developmental decrease in the synaptic charge transfer; (5) the kinetic
properties of the mIPSCs depend on the postnatal age of the animal
(i.e., whether the animal is younger or older than 3 weeks postnatal)
and not on the maturational stage of the neuron; and (6) synaptic
GABAA receptors in developing neurons are differentially
sensitive to zolpidem and zinc, indicating subunit-dependent
alterations in the functional properties of the GABAA
channels during development.
Early functional GABAergic synapses on immature granule cells
The rate of granule cell generation reaches its peak between P5
and P7, at approximately 50,000 neurons per day (Schlessinger et al.,
1975). Previous studies have shown that GABAergic neurons are born
prenatally (Schlessinger et al., 1978; Amaral and Kurz, 1985; Lubbers
et al., 1985), and by the end of the first postnatal week, they make
synaptic contacts on granule cell dendrites as well as somata (Lubbers
and Frotscher, 1988; Seress and Ribak, 1988, 1990). Although GABAergic
responses have been shown to occur in developing hippocampal and
cortical pyramidal cells (Mueller et al., 1984; Kriegstein et al.,
1987; Janigro and Schwartzkroin, 1988; Ben-Ari et al., 1989; Gaiarsa et
al., 1990; Blanton and Kriegstein, 1991; Luhmann and Prince, 1991;
Zhang et al., 1991; Hosokawa et al., 1994; Fleidervish and Gutnick,
1995), the functional properties of the early GABAA
receptor-mediated synaptic transmission in the late-developing dentate
granule cells are not well understood. The data presented here
demonstrate that the overwhelming majority of dentate granule cells of
the early postnatal rat possess functionally active GABAergic synaptic
inputs [interestingly, no glutamatergic synaptic events can be
observed at this time in granule cells (our unpublished
observations)], similar to CA1 and CA3 pyramidal cells (Ben-Ari et
al., 1989; Hosokawa et al., 1994; Gaiarsa et al., 1995). Importantly,
these first GABAergic synaptic inputs are likely to play significant
roles in neuronal development (see below).
Properties of the first GABAergic synaptic currents in dentate
granule cells
GABA is known to exert various effects on developing neurons
(Hansen et al., 1984, 1988; LoTurco et al., 1995; Behar et al., 1996;
Marty et al., 1996). Some of these effects can be observed when GABA is
simply included in the incubation medium in cultures (e.g., Behar et
al., 1996), i.e., presumably via the activation of mostly extrasynaptic
receptors. Recent results, however, indicate that the synaptic release
of GABA also plays an important role in neuronal maturation. Indeed,
GABAA receptor-mediated synaptic potentials summate and
cause enough depolarization to open voltage-gated Ca2+ channels and remove the Mg2+
block of NMDA channels, leading to increases in
[Ca2+]i (Ben-Ari et al., 1989;
Cherubini et al., 1991; Yuste and Katz, 1991; Gaiarsa et al., 1995;
Owens et al., 1996); GABA is depolarizing in both the adult and
juvenile dentate granule cells (Staley and Mody, 1992; Soltesz and
Mody, 1994; Liu et al., 1996). In the adult, summation of fast
GABAA receptor-mediated postsynaptic currents, e.g., in
hippocampal 40 Hz oscillations, requires highly precise synchronous
release of GABA from presynaptic interneuronal axons (Buzsáki et
al., 1983; Soltesz and Deschênes, 1993; Whittington et al.,
1995). It seems reasonable to assume that the slower rising and slower
decaying GABAA receptor-mediated synaptic signals in developing dentate granule cells may serve to provide a larger window
of opportunity for the summation of postsynaptic GABA currents at a
time when precision in the timing of action potentials may not have
reached adult values (McCormick and Prince, 1987). Furthermore, the
greater charge transfer is likely to lead to more effective depolarization and presumable Ca2+-channel
activation.
Interestingly, several properties of the early GABAergic synapse
seem to show marked differences between brain areas. For example,
cerebellar granule cells show (1) a developmentally increasing activation of receptors by ambient GABA (evidenced by the larger bicuculline-sensitive baseline "noise" in mature cells), likely contributing to receptor desensitization; (2) a developmental increase
in the contribution of the fast exponential to the spontaneous IPSC
(sIPSC) decay (in these cells the sIPSC decay is described by double
exponentials), related to receptor desensitization and a developmental
increase in the expression of the 6 subunit; (3) a developmental
decrease in the sIPSC amplitude; and (4) no change in the rise time
constant (Tia et al., 1996). By contrast, in dentate granule cells (1)
there is no significant change in the baseline noise, (2) the decay
phase can be described by a single exponential in both adult and
developing cells, (3) the mIPSC amplitude does not change, and (4) the
mIPSC rise time constant decreases during development. These data
suggest that the early GABAergic system may exhibit a staggering
variety of phenotypes (Kraszewski and Grantyn, 1992; Oh et al., 1995),
indicating that GABAA synaptic transmission may play
developmental roles that are specific to various brain areas.
Possible mechanisms underlying the slow mIPSC kinetics
Recent anatomical studies indicate that transient GABAergic
neurons of the inner molecular layer possess terminal-like varicosities in close juxtaposition to granule cells (Dupuy and Houser, 1996). The
anatomical studies also suggested that granule cells may receive their
first GABAergic contacts on their most proximal dendrites (Lubbers and
Frotscher, 1988; Dupuy and Houser, 1996), followed by the innervation
of the somatic region by basket cells (Seress et al., 1989); however,
the unchanged mIPSC amplitude from P0 to adult argues against a major
influence of electrotonic filtering on the mIPSC kinetics, because a
more remote synaptic location (in the adult granule cells, mIPSCs are
generated at synapses close to the soma) would severely affect the IPSC
amplitudes (Soltesz et al., 1995). In fact, filtering affects the
amplitude more than the rise time, because the amplitude decreases
exponentially whereas the rise time increases only linearly as the
synapse is moved from the soma toward the distal dendrites (Soltesz et
al., 1995). Furthermore, P5-P14 cells also showed slower kinetics, and
at these later postnatal dates GABAergic synapses have been
demonstrated on granule cell somata (Seress and Ribak, 1988; Seress et
al., 1989). A related issue is that in the early postnatal dentate, GABAergic synaptic junctions are difficult to identify morphologically (Dupuy and Houser, 1996), raising the possibility of a developmental difference in synaptic cleft distance; however, a larger cleft distance
would not only slow the kinetics, but would also decrease the mIPSC
amplitude (Evers et al., 1989). Similarly, because GABA uptake blockers
do not prolong the mIPSC decay in granule cells (Otis and Mody, 1992;
Thompson and Gähwiler, 1992), an increased uptake in adult cells
cannot explain the speeding up of the GABA currents during development
(also, a weaker uptake in immature cells is unlikely to underlie the
slower rise kinetics). Differential GABAA receptor
properties resulting from developmental changes in subunit composition
(Mathews et al., 1994; Oh et al., 1995; Gibbs et al., 1996), indicated
by the zolpidem and zinc data, are likely to be a major factor in
determining the slow mIPSC kinetics. Because the 1, 2, and 1
subunits significantly increase their expression levels around the
second and third postnatal weeks in the dentate (Killisch et al., 1991;
Poulter et al., 1992; Fritschy et al., 1994) and are known to influence
the time course of GABAA signals in expression systems
(Angelotti and Macdonald, 1993; Saxena and Macdonald, 1994; Gingrich et
al., 1995; Dominguez-Perrot et al., 1996), it seems likely that the
developmentally regulated expression of all of these three subunits
contributes to the observed kinetic and pharmacological changes in
GABAA IPSCs in dentate granule cells. An exciting
additional possibility, to be explored in future studies, is that age-
and subunit-dependent modification of the existing and the newly
synthesized receptor subunits may also contribute to the developmental
changes of mIPSC kinetics.
Temporal profile of the developmental changes in
mIPSC kinetics
Our results show that statistically significant change in the
mIPSC kinetics occurred only after the end of the second postnatal week. In addition, before the third week there was no difference between the mIPSC kinetics in granule cells, which on the basis of
their dendritic morphology seemed to be at different stages of neuronal
development. These findings indicate that the changes in kinetics do
not occur at a predetermined time after the last mitosis of the cell.
Rather, the kinetic changes in mIPSCs around the third postnatal week
are likely to be triggered by signals that affect most granule cells at
approximately the same time, regardless of their developmental stage.
It will be of great interest in future studies to identify the nature
of the signals that determine the developmental changes in GABAergic
synaptic signaling.
FOOTNOTES
Received Jan. 16, 1997; revised March 11, 1997; accepted April 17, 1997.
This work was supported by March of Dimes Basil O'Connor Research
Scholar Award (5-FY95-1143) and the American Epilepsy Society (EFA-21311) to I.S. We thank Ms. G. Sandor for expert technical assistance, Dr. J. Dempster for providing the Strathclyde
Electrophysiology Software, and Dr. Y. De Koninck for the Synapse
software.
Correspondence should be addressed to Dr. Ivan Soltesz, Department of
Anatomy and Neurobiology, University of California, Irvine, CA
92697-1280.
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