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The Journal of Neuroscience, May 15, 2001, 21(10):3580-3592
Layer-Specific Intracolumnar and Transcolumnar Functional
Connectivity of Layer V Pyramidal Cells in Rat Barrel Cortex
Dirk
Schubert1, 2,
Jochen F.
Staiger2,
Nichole
Cho2,
Rolf
Kötter2, 3,
Karl
Zilles2, 4, and
Heiko J.
Luhmann1
1 Institute of Neurophysiology, 2 C. & O. Vogt-Institute for Brain Research, 3 Institute of
Morphological Endocrinology and Histochemistry, University of
Duesseldorf, D-40001 Duesseldorf, Germany, and 4 Institute
of Medicine, Research Center Juelich, D-52425 Juelich, Germany
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ABSTRACT |
Layer V pyramidal cells in rat barrel cortex are considered to play
an important role in intracolumnar and transcolumnar signal processing.
However, the precise circuitry mediating this processing is still
incompletely understood. Here we obtained detailed maps of excitatory
and inhibitory synaptic inputs onto the two major layer V pyramidal
cell subtypes, intrinsically burst spiking (IB) and regular spiking
(RS) cells, using a combination of caged glutamate photolysis,
whole-cell patch-clamp recording, and three-dimensional reconstruction
of biocytin-labeled cells. To excite presynaptic neurons with laminar
specificity, the release of caged glutamate was calibrated and
restricted to small areas of 50 × 50 µm in all cortical layers
and in at least two neighboring barrel-related columns. IB cells
received intracolumnar excitatory input from all layers, with the
largest EPSP amplitudes originating from neurons in layers IV and VI.
Prominent transcolumnar excitatory inputs were provided by presynaptic
neurons also located in layers IV, V, and VI of neighboring columns.
Inhibitory inputs were rare. In contrast, RS cells received distinct
intracolumnar inhibitory inputs, especially from layers II/III and V. Intracolumnar excitatory inputs to RS cells were prominent from layers
II-V, but relatively weak from layer VI. Conspicuous transcolumnar
excitatory inputs could be evoked solely in layers IV and V. Our
results show that layer V pyramidal cells are synaptically driven by
presynaptic neurons located in every layer of the barrel cortex. RS
cells seem to be preferentially involved in intracolumnar signal
processing, whereas IB cells effectively integrate excitatory inputs
across several columns.
Key words:
barrel cortex; layer V; pyramidal cell; burst spiking; regular spiking; functional connectivity; excitatory inputs; inhibitory
inputs; morphology; electrophysiology; biocytin; caged glutamate; somatosensory; slices
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INTRODUCTION |
Cortical information processing is
mediated by complex interactions between local neuronal circuits within
functional columns involving several classes of excitatory and
inhibitory neurons. The barrel field in the primary somatosensory
cortex of rodents is a particularly useful model for the investigation
of cortical columnar organization and signal processing, because the
functional columns can be recognized even in unstained living slices
(Agmon and Connors, 1991 ; Kötter et al., 1998). Here neuronal
clusters in layer IV (barrels) are related to principal whiskers on the contralateral side of the face in a one-to-one relationship (Woolsey and Van der Loos, 1970; Welker and Woolsey, 1974). Together with supragranular and infragranular neurons, in register with a barrel, they form a functional (barrel-related) column and respond
preferentially to stimulation of the whisker, which is
topographically related to the barrel within this column
(Armstrong-James, 1975; Simons, 1978). However, substantial signal
integration occurs not only within but also between barrel-related
columns. Because of the size of their receptive fields, which can
comprise a multitude of whiskers (Simons, 1985; Zhu and Connors, 1999),
pyramidal cells in supragranular and infragranular layers are
considered to play a crucial role in this signal integration (Staiger
et al., 2000).
In layer V of the cerebral cortex, two major classes of pyramidal cells
have been described: intrinsically burst spiking (IB) and
regular spiking (RS) cells (Connors et al., 1982; Chagnac-Amitai et
al., 1990; Larkman and Mason, 1990). The thick, tufted IB cells are
capable of discharging high-frequency bursts of action potentials and
show extensive horizontal axonal projections within infragranular layers and diverse corticofugal projections (Kasper et al., 1994). The
dendritically rather sparsely arborizing RS cells discharge more
regularly and project extensively to supragranular layers (Chagnac-Amitai et al., 1990) and to ipsilateral and contralateral cortical areas (Wise and Jones, 1976). Extensive synaptic coupling between pyramidal cells within layer V (Markram et al., 1997) and
between pyramidal cells in layer II/III and layer V (Reyes and Sakmann,
1999) was demonstrated using paired recordings (Thomson et al., 1993;
Thomson and Deuchars, 1994). Moreover, layer V pyramidal cells receive
inhibitory inputs from different laminar origins, and the spatial
organization of these inputs varies with the class of the pyramidal
cell (Nicoll et al., 1996). These findings indicate the existence of
complex excitatory and inhibitory inputs modulating the functional
status of layer V pyramidal cells. To receive detailed information
about the spatial distribution of synaptic inputs, it is necessary to
stimulate numerous presynaptic sites covering a sufficiently large
cortical area and to construct a synaptic input map for each single
cell. Thus we investigated the spatial distribution and strength of
excitatory and inhibitory synaptic inputs onto layer V pyramidal cells
using a combination of caged glutamate photolysis and whole-cell
patch-clamp recordings. Thereby we obtained detailed maps of
layer-specific intracolumnar and transcolumnar functional connectivity
of electrophysiologically characterized and morphologically
reconstructed RS and IB cells that demonstrate a differential
involvement of the two cell types in local cortical circuits.
Part of this study was published previously in abstract form (Schubert
et al., 2000).
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MATERIALS AND METHODS |
Slice preparation and chemicals. We prepared coronal
slices from rat somatosensory cortex containing the barrel cortex
(Par1) (Paxinos and Watson, 1986). Male Wistar rats (postnatal days
18-22) were deeply anesthetized with enflurane and decapitated. Blocks of tissue containing the barrel cortex were excised, quickly removed from the skull, and stored in ice-cold artificial CSF (ACSF)
oxygenated with carbogen (95% O2/5%
CO2). Normal ACSF consisted of (in
mM): 124 NaCl, 1.25 NaH2PO4, 26 NaHCO3, 1.6 CaCl2, 1.8 MgCl2, 3 KCl, 10 glucose, at pH 7.4. To block
synaptic transmission, modified ACSF containing 0.2 CaCl2, 4 MgSO4 (low
Ca2+/high
Mg2+ ACSF) was used. The tissue block was
glued to the chilled platform of a Vibratome (Series 1000, TPI, St.
Louis, MO) and submerged in ice-cold carbogenated ACSF. Slices of 300 µm nominal thickness were cut and incised along the midline to
separate the hemispheres. The slices were stored in an incubation
chamber containing carbogenated ACSF at 34°C for at least 1 hr. The
slices were then transferred to the recording chamber and submerged in
ACSF at a flow rate of ~1 ml/min at 32°C. During the application of
caged glutamate, a total amount of ~5 ml ACSF containing the caged
compound was continuously oxygenated and recirculated. The caged
glutamate (L-glutamic acid,
 -[ -carboxy-2-nitrobenzyl]ester; Molecular Probes, Eugene, OR)
was dissolved in ACSF and added to the circulating ACSF, resulting in a
1 mM concentration.
Identification of layer V pyramidal neurons. The slices were
placed in a fixed stage, submerged chamber under an upright microscope (Axioskop FS, Carl Zeiss, Göttingen, Germany) fitted with a 2.5× and a 40× water-immersed objective (40×/0.75 W; Olympus, Hamburg, Germany). The barrel field was visualized at low magnification (Fig.
1), and a target region in layer V, which
was in vertical register with a barrel, was selected. Individual
pyramidal cells were visually identified at 40× magnification using
infrared enhanced quarter-field illumination. A bipolar tungsten
stimulating electrode was placed in deep layer VI of the same
column.
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Figure 1.
Photomicrograph taken directly after an experiment
of a living unstained coronal slice of the somatosensory cortex with
positioned electrodes. The tip of the patch electrode points at a
pyramidal cell in layer V (position marked by a gray
triangle). The bipolar stimulation electrode is placed in the
white matter (wm) for electrical stimulation of the
afferents. The grid superimposed on the micrograph
indicates the relative location and the extent of the area typically
used for investigating the functional connectivity of layer V pyramidal
cells. Fields (450) 50 × 50 µm in size were stimulated in
sequence at 10 sec intervals covering all cortical layers and at least
two barrel-related columns. The two barrels in layer IV located within
the investigated area are outlined by white lines. Roman
numerals indicate cortical layers.
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Electrophysiology. Whole-cell patch-clamp recordings from
the selected pyramidal cells were performed in current-clamp mode using
patch pipettes (4-6 M ) pulled from borosilicate glass capillaries (1.5 mm outer diameter, 1.16 mm inner diameter; Science Products, Hofheim, Germany) on a Narishige PP-830 puller (Narishige, Tokyo, Japan). The patch pipettes were filled with (in
mM): 13 KCl, 117 K-gluconate, 10 K-HEPES, 2 Na2ATP, 0.5 NaGTP, 1 CaCl2,
2 MgCl2, 11 EGTA, and 1% biocytin. After
obtaining a stable seal of >1 G, the whole-cell configuration was
achieved by gentle suction. The cells were electrophysiologically
characterized by recording their resting membrane potential and their
intrinsic membrane properties under current-clamp conditions by
injecting depolarizing and hyperpolarizing current pulses. Orthodromic
synaptic responses were elicited with the bipolar stimulating electrode
(200 µsec duration at 0.1 Hz). To exclude possible influences of
caged glutamate on the properties of the recorded cells,
electrophysiological characterization and long time recordings were
performed in ACSF alone as well as in ACSF containing caged glutamate.
Their results were virtually identical.
Scanning of glutamate evoked activity. The setup that we
used for the photolysis of caged glutamate has been described
previously (Kötter et al., 1998). However, to implement
single-cell recordings, some modifications were necessary. We added a
circular linear-wedge neutral-density filter into the light path
(Dr = 0.0-2.0) (Melles Griot, Irvine,
CA) for the exact calibration of the illumination intensity. The light
pulses (~500 µsec) were focused on areas that were 50 × 50 µm large, with the focus plane ~50-80 µm deep in the slice,
which was equal to the depth of the recorded cell soma. The membrane
potential was recorded during every photostimulus. In the beginning of
the study, fields at varying distances from a recorded soma were
stimulated, always with use of the same stimulation strength. This was
done to ensure that the photostimulation provided layer-specific
excitation. In ACSF, aside from layer V pyramidal cells
(n = 42), other neurons in layers II/III, IV, V and VI
also were recorded at the resting membrane potential
(Vrmp) of the cells (n = 19). In none of these control experiments could action potentials be elicited by photostimulation at distances >100 µm from
the soma. In two of five pyramidal cells in layer II/III, no
suprathreshold activation was evoked from any of the tested fields.
Every 10 sec the stimulation area was moved in a meandering fashion
across a rectangular field for further scanning in steps of 50 µm
(Fig. 1). While the synaptic connectivity was mapped, the cell was held
at a potential (Vhold) of  60 mV in
current-clamp mode to reveal hyperpolarizing inhibitory inputs. As
shown in Figure 1, the scanned cortical areas included at
least two barrel-related columns from layers I-VI, and thus up to 450 different fields were stimulated without any intermittent gaps. To
determine the spatial distribution of glutamate-evoked direct activity
in the recorded cell, we blocked synaptic transmission using ACSF
containing low Ca2+/high
Mg2+. The intrinsic properties of the
recorded cell were controlled before and after termination of each map.
Data acquisition and analysis. The signals were amplified
(SEC-05L; npi-electronics, Tamm, Germany), filtered at 3 kHz, and digitized using an ITC-16 interface (Instrutech, Great Neck, NY). Data
were recorded, stored, and analyzed with PC-based software (TIDA 4.1 for Windows; Heka Electronik, Lambrecht, Germany). After recording, the
slices were photographed in the bath chamber to document the topography
of barrel-related columns and laminae as well as the respective
position of the patch and stimulating electrode. Slices were then fixed
in 4% buffered paraformaldehyde and stored at 4°C. For visualization
of the biocytin-filled neurons, the slices were processed using a
previously described protocol (Angulo et al., 1999). Reconstruction and
morphological analyses of the biocytin-labeled neurons were made using
a Nikon Eclipse 800 (Nikon, Ratingen, Germany) attached to a computer
system (Neurolucida; Microbrightfield Europe, Magdeburg, Germany). IB
and RS cells were compared in terms of the following morphological
properties: soma area, total length of apical and basal dendrites,
total number of branches of the apical dendrite, and the maximal
diameter of the apical trunk. The data were not corrected for tissue
shrinkage. The reconstructed cells were superimposed onto the
photomicrograph of the native slice using standard graphics software.
Different maps of glutamate-induced activity obtained in low
Ca2+/high
Mg2+ containing ACSF were constructed
using (1) flash evoked peak amplitudes and (2) delays between stimulus
and onset of activity. For maps in normal ACSF, the following
properties of stimulus-induced activity were analyzed within a time
window of 150 msec after stimulus for each single trace: (1)
delay-to-onset of stimulus-evoked activity, (2) occurrence of
IPSPs, (3) maximal peak amplitude, and (4) integral of all
EPSPs. Only subthreshold responses with amplitudes of >0.2 mV
were included for further analysis. In control experiments using
repetitive photostimulation, we additionally analyzed (1) the delay
between stimulus and action potential threshold (action potential
latency), (2) the peak amplitude of the first EPSP, and (3) 20-80%
rise-time of the first EPSP. Spontaneous activity with amplitudes of
>0.2 mV was very rare and, when present, was excluded from further
analysis. Response properties that were analyzed were transformed into
pseudocolored values using the software Origin 6.0 (Microcal Software,
Northampton, MA), and the resulting maps were superimposed on
the respective sites on the micrographs. Statistical analysis was
performed using repeated measures ANOVA with post hoc
pair-wise comparisons (Bonferroni corrected) and unpaired two-tailed
Student's t test (SPSS 9; SPSS Inc., Chicago, IL). Data are
presented as mean ± SD.
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RESULTS |
In the present study, we investigated 55 layer V pyramidal cells
in rat barrel cortex. For 27 layer V IB/doublet spiking cells and 28 layer V RS cells, whole-cell patch-clamp recordings were combined with
topographic mapping of glutamate-induced activity. Complete maps in
ACSF including all cortical layers and at least two barrel-related
columns were obtained for seven IB cells and eight RS cells. Partially
mapped cells (11 IB cells, 12 RS cells) were used for complementary
verification of the results obtained from the completely mapped cells.
The remaining cells were used for control experiments (see Materials
and Methods). Only cells with a stable resting membrane potential
negative to 60 mV during the whole experiment were included in the analysis.
Electrophysiological and morphological identification of RS and
IB cells
As indicated by previous studies, layer V pyramidal neurons can be
divided into RS and IB cells according to their firing properties, their synaptic input pattern in response to orthodromic stimulation, and their specific morphology (Connors et al., 1982; Chagnac-Amitai et al., 1990; Larkman and Mason, 1990; Amitai, 1994;
Williams and Stuart, 1999; Hefti and Smith, 2000). In accordance with
these studies, we found that IB cells responded to injection of a just
suprathreshold depolarizing current pulse with an initial high-frequency burst consisting of two to three action potentials with
decreasing amplitudes mounted on a depolarizing after potential (DAP)
(Fig. 2A). This initial
burst with a first interspike interval (ISI) of 175 ± 22 Hz
(n = 17) was followed either by rhythmic action
potential (AP)-firing or by single APs showing longer ISIs. Injection
of current pulses with increasing amplitudes did not alter the first
ISI but increased the number of action potentials in the initial burst
to three to six spikes. In 10 cells, just suprathreshold as well as
increased current injections reproducibly induced doublets of APs at a
mean first ISI of 152 ± 27 Hz (Fig. 2B). Except
for the different response pattern to depolarizing current injection,
these doublet spiking cells were indistinguishable from IB cells and
showed the same response to orthodromic stimulation and the same
morphology. Thus, doublet spiking cells were added to the group of IB
cells in accordance with the description by Schwindt et al. (1997). RS
cells, however, responded to suprathreshold current injection with a
series of single APs (Fig. 2C). In 11 of 28 RS cells, the
firing rate became more or less constant after an initial frequency
adaptation [comparable to RS1-type in Hefti and
Smith (2000)]. In the remaining cells, the firing rate adaptation continued for the duration of the depolarizing current pulse. In 14 of
28 RS cells, APs were followed by a small DAP (comparable to
RS2-type). However, rhythmic AP firing or
high-frequency bursts/doublets of APs were never observed in RS cells.
The average resting membrane potential
(Vrmp) and the membrane resistance
(Rm) were not significantly different
between IB cells (Vrmp = 62.6 ± 3.2 mV; Rm = 133 ± 64 M;
n = 27) and RS cells
(Vrmp = 63.7 ± 3.7 mV;
Rm = 202 ± 124 M;
n = 28).
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Figure 2.
Action potential firing pattern
(A-C) and synaptic responses
(D, E) of layer V pyramidal cells.
A, Response of an intrinsically burst spiking cell (IB
cell) to injection of a suprathreshold depolarizing current pulse at
resting membrane potential. The initial burst consists of an action
potential followed by a DAP with three spikes of decreasing amplitude.
The initial burst is followed by a sequence of single APs.
B, In the doublet spiking cell, the intracellular
current pulse elicits an initial action potential followed by a small
DAP with one spike and subsequent single APs with no spike-frequency
adaptation. C, In the regular spiking cell (RS cell),
the depolarizing current evokes a train of single APs without any DAP.
D, Postsynaptic responses of an IB cell to strong
orthodromic stimulation (2× threshold; arrow) at
different membrane potentials. The stimulus evokes a burst and a long
lasting EPSP. E, Orthodromic synaptic stimulation of the
RS cell elicits a single spike and an EPSP truncated by a fast (*) and
a slow (**) IPSP.
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We also used orthodromic synaptic stimulation for a functional
characterization of the two cell types. As demonstrated in Figure
2D, orthodromic stimulation evoked an
EPSP, eliciting a burst of action potentials in IB cells with no
visible IPSP. In contrast, in 19 of 28 RS cells, the initial EPSP was
followed by a prominent fast and slow IPSP (Fig. 2E).
The remaining nine RS cells showed no detectable IPSPs.
All cells were labeled with biocytin for subsequent morphological
identification. All completely filled IB and RS cells showed an apical
dendrite reaching layer I (n = 25). A quantitative
evaluation of cell type-specific morphological properties of
reconstructed IB and RS cells is given in Table
1. In agreement with the studies mentioned before, large triangular somata and thick apical dendrites were typical features of IB cells (Fig.
3A). The apical
dendrite usually possessed numerous oblique collateral branches. The
main trunk started to bifurcate in layers IV or II/III, giving rise to
a rich terminal tuft. The basal dendrites were also extensively ramified. In contrast, RS cells possessed a smaller ovoid soma with a
thinner apical trunk and a less ramified apical dendrite (Fig.
3B).
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Figure 3.
Photoreconstructions of a biocytin-stained
intrinsically burst spiking cell (A) and a
regular spiking cell (B) in a 300-µm-thick
coronal section of the barrel cortex. A, The IB cell
shows a large soma and a thick apical dendrite, which gives off oblique
collateral branches in layer V and bifurcates in layer IV, giving rise
to a rich terminal tuft. The basal dendrites are also extensively
ramified. B, The RS cell shows a smaller soma and a
thinner apical dendrite. The apical dendritic tree as well as the basal
dendrites are ramified less extensively.
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Direct effects of uncaged glutamate
To investigate the direct effects of uncaged glutamate on
functional properties of the recorded cell, we performed experiments in
ACSF containing low Ca2+/high
Mg2+ to block synaptic transmission. After
30 min of perfusion with low Ca2+/high
Mg2+ ACSF, even strong electrical stimuli
were not capable of evoking postsynaptic responses in the recorded
neuron (n = 4 IB and 5 RS cells). The photolysis of
caged glutamate within a field of tissue containing dendritic
extensions of the recorded cell led to a transient depolarization (Fig.
4A,B).
For both cell types, 20 repetitive flashes at 10 sec intervals on a
selected proximal dendritic field revealed a stable pattern of evoked
depolarizations. Perisomatic stimulation induced strong depolarizations
of 15-20 mV that reliably elicited a single action potential, doublet, or burst in accordance with electrical characterization (Fig. 4C,D). However, depending on the size of the
depolarization amplitude, short trains of action potentials after the
initial response also could be elicited (Dantzker and Callaway, 2000).
The delay-to-onset times within distances of  100 µm from the soma
were <1 msec, and the estimated rise-times were >5 msec. At distances
of >500 µm from the soma, the 20-80% rise-times could increase up
to 30 msec. Neither the delay-to-onset of activation (Fig.
5A) nor the 20-80%
rise-times (Fig. 5B) changed significantly during repetitive flash activation. In contrast, the depolarization amplitudes (Fig. 5C) and action potential latencies (Fig. 5D) were
more variable.
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Figure 4.
Repetitive stimulation of proximal
apical dendritic (A, B) and perisomatic
(C, D) fields of an IB (A,
C) and an RS cell (B, D)
via localized release of caged glutamate. The bathing medium contained
0.2 mM Ca2+ and 4 mM
Mg2+ to block synaptic transmission.
Inset, Schematic diagram of a pyramidal cell and
relative positions of the stimulated areas. A,
B, Photolysis of caged glutamate in 50 × 50 µm
large fields positioned ~150 µm away from the soma of the recorded
cells and (C, D) on the apical dendrite
close to the soma. Repetitive stimulation at 10 sec intervals reliably
induces a membrane depolarization, which only during perisomatic
stimulation triggers a burst (C) or a single
action potential (D). Twenty subsequent traces
are superimposed to illustrate the stability of the responses to caged
glutamate photolysis. The recordings were performed at resting membrane
potential of 62 mV in the IB cell and 68 mV in the RS cell.
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Figure 5.
Properties of repetitively evoked
activity in bathing solution containing low
Ca2+/high Mg2+. In an area of
50 × 50 µm located on the apical dendrite ~150 µm away from
the soma, caged glutamate was photolyzed 20 times at 10 sec intervals
at resting membrane potential. Data are normalized to the first
response and are presented as mean ± SD
(A-C: n = 3 RS cells
and 3 IB cells; D: n = 2 RS cells
and 2 IB cells). A, Delay-to- onset of activation times.
B, Rise-times (20-80%) of the responses.
C, Amplitudes of the elicited depolarizations.
D, Delay between stimulation and action potential
threshold (action potential latency) varied between 80 and 120% of the
initial control value.
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To determine the spatial distribution of the direct glutamate-induced
activity under low Ca2+/high
Mg2+ conditions, we stimulated 250 fields
and converted the depolarization amplitudes or the delay-to-onset of
activation into color-coded maps (Fig. 6)
(n = 4 IB and 4 RS cells). In the matched figure of the
native slice and the reconstructed cell, each colored square indicates
the location of a stimulated field of tissue where a depolarizing
response was evoked. Figure 6 illustrates the spatial distribution of
the glutamate-induced activity for an IB cell. Membrane depolarizations
were observed only in fields containing dendritic extensions of the
recorded cell. Highest response amplitudes were induced at perisomatic
locations and along the proximal dendrites; lowest response amplitudes
were induced at peripheral locations of the basal dendrites and at
distal parts of the apical dendrite. Action potentials were evoked only
by flashing fields very close to the soma. The delay-to-onset of
activation (Fig. 6B) and the rise-time (20-80%;
data not shown) directly correlated with the distance of the flashed
field to the recording site. The stimulation of fields at or near the
soma caused an almost immediate depolarization (Fig.
6D3). Longer delay-to-onset times were observed by
flashing the apical tuft near the pial surface (Fig.
6D1). A linear regression of the data resulted in the
calculation of an average electrotonic propagation velocity of 0.26 m/sec along the dendrites (Fig. 6E).
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Figure 6.
Topographic maps of depolarization amplitude and
delay-to-onset of activation times of an IB cell in low
Ca2+/high Mg2+-containing
solution. The photomicrograph of the native slice was superimposed on
the respective Neurolucida reconstruction of the somatodendritic
domains of the IB cell and the map illustrating the amplitudes of
induced activity (A) or the delay-to-onset of
activation (B). The size of the investigated area
is outlined in black. Stimulated fields without any
correlated activity are transparent. The colors indicate
the depolarization amplitudes, action potentials, or delay-to-onset
times (see color scale). The positions of the stimulated
fields corresponding to the traces in D are marked
1-3. A, In low
Ca2+/high Mg2+ ACSF, activity can
be evoked only by stimulation of fields containing dendritic extensions
of the IB cell. Photolysis induces action potentials in perisomatic
fields only. B, The delay-to-onset times correlate with
the distance of the stimulation site to the soma. Perisomatic
stimulation leads almost instantly to an activity (<0.2 msec), whereas
activity evoked by stimulation near the pial surface reaches the soma
after >5 msec. C, Current-voltage relationship
identifies the recorded cell as an IB cell. Inset, Photo
of the native slice marking the sector presented in A
and B (outlined in white).
D, Responses to photolysis of caged glutamate at
positions indicated in A and B. With
increasing distance from the soma, depolarization amplitudes decrease,
whereas the delay-to-onset times increase. Fast suprathreshold
depolarization inducing a burst of APs is elicited at stimulation site
3 at the soma. E, Correlation between
delay-to-onset times and distance of the stimulation site to the soma
for three RS cells and three IB cells. Data were used to calculate an
electrotonic propagation velocity of 0.26 m/sec (red
line, r = 0.967).
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Characterization of synaptically evoked inputs onto layer V
pyramidal cells
In experiments performed in normal ACSF, the uncaged glutamate was
able to induce (1) activity resulting from direct stimulation of
dendritic extensions of the recorded cell and (2) EPSPs and IPSPs
after activation of presynaptic excitatory and inhibitory neurons,
respectively. Repetitive stimulation of selected sites was used to
characterize the properties of synaptically evoked activity
(n = 4 RS and 4 IB cells). As demonstrated in Figure 7, the recorded IB cell
received distinct excitatory and inhibitory synaptic inputs from
presynaptically activated neurons. Repetitive stimulation of some
fields reliably elicited IPSPs with stable rise-time and delay-to-onset
time (Fig. 7A). However, the amplitude of the IPSPs varied
from trial to trial. In other fields, unlike the IPSPs, EPSPs were
initiated during repetitive stimulation, with a failure rate of 5-40%
(as at site 2), but with relatively stable amplitudes and rise-times
(Fig. 7B). The delay-to-onset times of the EPSPs varied
between 5 and 50 msec. Furthermore, the flash often evoked two or
multiple EPSPs. As under low Ca2+/high
Mg2+ conditions, perisomatic stimulation
reliably elicited an action potential (Fig. 7C).
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Figure 7.
Repetitive postsynaptic responses
recorded in normal ACSF in an RS cell
(Vrmp = 64 mV). Fields
1 and 2 containing no dendritic
extensions of the recorded cell were stimulated 20 times at 10 sec
intervals. A perisomatic field was stimulated 10 times (field
3). The left column shows a
representative single response of the superimposed traces recorded from
the RS cell. A, Stimulation of field 1
induces a reliable inhibitory input onto the RS cell without any
failures. B, Stimulation of field 2
induces excitatory inputs onto the RS cell. C, The
perisomatic stimulation (field 3) reliably induces a
suprathreshold depolarization. The AP latencies vary between 15 and 25 msec.
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Figure 8A shows
recordings of two populations of EPSPs after repetitive stimulation at
the same site. The two populations varied not only in their delay to
onset but also in their order of appearance (Fig.
8A,B). However, the two populations
differed significantly in their mean amplitudes (EPSP1: 2.9 ± 0.2 mV; EPSP2: 1.3 ± 0.2 mV; n = 15;
p < 0.001, t test), integrals (EPSP1:
0.03 ± 0.005 mVs; EPSP2: 0.012 ± 0.004 mVs;
p < 0.001), and rise-times (EPSP1: 1.1 ± 0.1 msec; EPSP2: 1.6 ± 0.2 msec; p < 0.001).
Therefore, these parameters could be used to distinguish between the
EPSPs (Fig. 8C,D). Consequently, the
delay-to-onset times could not be used as an indicator for the site of
the synaptic input onto the recorded cell.
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Figure 8.
Properties of excitatory inputs onto
layer V pyramidal cells. Excitatory inputs onto an IB cell
(Vrmp = 72 mV) induced by repetitive
stimulation (15×, 10 sec intervals) of a field located in layer VI
~250 µm from the soma. The stimulation induced two distinct EPSPs
with an average amplitude of 2.9 ± 0.2 mV (EPSP1) and 1.3 ± 0.2 mV (EPSP2). Superimposed traces (A1) and selected
single traces (A2, A3) demonstrate the
large variability in the delay-to-onset times of EPSP1 and EPSP2.
B, Variability of the delay-to-onset times. Failure rate
is 17% for EPSP1 and 33% for EPSP2. Plot of the relationship between
EPSP amplitude and integral (C) and plot of the
relationship between EPSP amplitude and rise-time
(D) demonstrate that both populations of EPSPs
can be clearly differentiated.
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Intracortical inputs onto layer V pyramidal cells
For the topographic mapping of the functional connectivity
we stimulated 450 different fields of 50 × 50 µm in size
comprising an area of all six cortical layers and two or more
neighboring barrel-related columns. Stimulation of fields containing
dendritic extensions of the recorded cells often resulted in a mixture
of direct nonsynaptic activation and synaptic events. Therefore it was
necessary to separate the direct nonsynaptic responses from the
synaptically evoked activity to obtain "pure" synaptic input maps.
Figure 9 shows the spatial distribution
of evoked responses recorded in low
Ca2+/high
Mg2+ ACSF (Fig. 9A) as well as
in normal ACSF (Fig. 9B) for an IB cell. Direct nonsynaptic
responses recorded in low Ca2+/high
Mg2+ ACSF reached the soma within 8 msec
(Fig. 9C, top panel). In normal ACSF, we
always observed a comparable amount of evoked events within the first 8 msec (Fig. 9C, bottom panel). The
remaining events were recorded with delay-to-onset times of >11 msec.
In accordance with the morphology of the cell, all responses
with delay-to-onsets 8 msec could be related to direct nonsynaptic activation of the dendritic extensions (Fig.
9B,D). Therefore, we could
construct maps specifically showing synaptic inputs to the recorded
cells (Fig. 9B). Aside from various subthreshold events,
several sites were found to induce action potentials >100 µm away
from the soma. This is explained by the fact that during mapping the
recorded cells were depolarized by up to 10 mV to reach
Vhold = 60 mV. Control stimulations
of the respective fields after mapping at
Vrmp never evoked APs (data not
shown).
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Figure 9.
Topographic maps of uncaged glutamate-induced
activity during blockade of synaptic transmission
(A) and in normal bathing solution
(B). A, Color-coded map of the
amplitudes of depolarizations evoked by direct dendritic activation
recorded at resting membrane potential
(Vrmp = 69 mV) in bathing solution
containing 0.2 mM Ca2+/4 mM
Mg2+. Fields eliciting an action potential are
marked in red. B, Responses recorded in
normal ACSF at a depolarized membrane potential
(Vhold = 60 mV) consist of IPSPs
(blue), action potentials (red), and
EPSPs of variable amplitudes (green to
orange). Fields that elicit a response with a delay of
<8 msec caused by direct dendritic activation are marked in
gray even when EPSPs were additionally elicited.
This separation was obtained by an analysis of the delay-to-onset times
as shown in C. Stimulation of distal fields in layer IV
elicited APs only at the depolarized holding potential of 60 mV, but
not at the resting membrane potential of the cell of 69 mV.
C, Delay-to-onset times calculated from responses
obtained from two IB and two RS cells recorded in low
Ca2+/high Mg2+-ACSF as well as in
normal ACSF. In low Ca2+/high
Mg2+-ACSF all responses were recorded within the
first 8 msec. In normal ACSF the delay-to-onset times of the first
response are given. Note that the responses with a delay-to-onset <8
msec are comparable to the responses recorded in low
Ca2+/high Mg2+-ACSF. The
remaining responses had delay-to-onset times >10 msec.
D, Representative responses recorded in low
Ca2+/high Mg2+-ACSF
(red) and normal ACSF (black) to
activation of fields as shown in A and B.
Suprathreshold depolarization was caused by direct perisomatic
activation (trace 1). Direct dendritic activation causes
a transient depolarization (trace 2). Activation of the
same site in normal ACSF induces an excitatory input to the IB cell
consisting of summed EPSPs (trace 3), in addition to the
direct dendritically evoked depolarization. Synaptic excitatory and
inhibitory inputs during stimulation of sites in ACSF are shown in
traces 4 and 5. In these and the
following maps, the borders of the barrels are outlined in
black.
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Typical spatial distribution and strength of synaptic inputs onto an IB
and an RS cell are illustrated in Figure
10. The maps clearly indicate that the
IB as well as the RS cell received excitatory inputs from neurons
located in layers II-VI within the same column and, to a lesser
degree, also from the adjacent barrel-related column. The spatial
distribution of fields providing excitatory inputs was generally
continuous in infragranular layers and more patchy in the granular and
supragranular layers. Especially in layers II/III, EPSPs could be
elicited predominantly in fields near the apical dendrite of the
recorded cells. In contrast to the EPSPs, inhibitory inputs were
spatially more limited to fields in layers II/III and V of the same
column.
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Figure 10.
Representative topographic maps of functional
connectivity of an IB cell (A) and an RS cell
(B) at Vhold = 60 mV. The maps illustrate the integrals of EPSPs recorded within 150 msec after stimulus, fields of origin for inhibitory inputs, and action
potentials. Note that the IB cells as well as the RS cells receive
excitatory inputs during stimulation of fields in layers II-VI. A
photomicrograph indicating the enlarged cortical area within the slice
(outlined in white) and the response of the cells to
injection of depolarizing and hyperpolarizing current pulses in normal
ACSF at Vrmp (IB cell: 70 mV; RS cell:
67 mV) are presented below the respective maps.
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Stimulation of presynaptic fields often elicited multiple EPSPs. To
estimate the strength of excitatory input we determined the integral of
all synaptically evoked excitatory events within a time window of 150 msec after stimulus. In several cases, photostimulation elicited
synaptically evoked events as well as a direct response. Whenever
possible, we separately calculated the integral of the synaptically
evoked events only. In the remaining cases the traces were excluded
from the integral analysis. The integrals of EPSPs ranged in 69% from
0.01 to 0.05 mVs. For both cell types, integrals obtained from fields
in layers II/III normally did not exceed these values. However, "hot
spots" of excitatory input could be found in layers IV, V, and VI,
mainly located intracolumnarly. In these fields the integrals comprised
a multitude of EPSPs and could reach 0.1-1 mVs. Especially in layer
IV, hot spots could be found in discrete patches adjoining fields
delivering no or very weak input. To analyze layer- and column-specific
distribution of excitatory input, the mean integrals values within each
layer and column were calculated. In general, excitatory input arising from intracolumnarly located fields was significantly stronger than
from transcolumnarly located fields (p = 0.001, ANOVA). Integrals of EPSPs arising from layer II/III were significantly
weaker than from layers IV (p = 0.03) and V
(p = 0.02). However, within the layers the
statistical analysis of excitatory integrals showed a high variability
because of the large range of integral values. Thus, a significant cell
type-dependent difference was not detectable.
Significant cell type-specific differences were found in the
distribution of excitatory and inhibitory synaptic inputs originating from the same and neighboring columns (p = 0.03). The quantitative analysis of the spatial distribution of
synaptic input demonstrates that both cell types received widespread
excitatory inputs from all cortical layers (Fig.
11A). The input was
most prominent from within their respective column
(p < 0.001). The prevalent source of excitatory
inputs onto IB cells was layer VI. On average, 88 ± 7% of the
intracolumnar and 54 ± 15% of the transcolumnar layer VI fields
elicited an EPSP in IB cells. For the remaining layers, average
intracolumnar inputs varied between 33 and 64%, and transcolumnar inputs varied between 19 and 43%. RS cells received most of their excitatory inputs from fields in layer V; 60 ± 17% of the
intracolumnarly and 28 ± 17% of the transcolumnarly located
fields delivered excitatory input during stimulation. For the remaining
layers the average intracolumnar inputs varied between 25 and 53%;
transcolumnar inputs varied between 8 and 21%. Intracolumnarly, a
significant difference between the amount of excitatory inputs onto IB
and RS cells was observed in layer VI only (p < 0.001, t test). IB neurons received significantly stronger
transcolumnar excitatory inputs from layer VI (p = 0.001, t test), layer IV(p = 0.05), and layer II/III (p = 0.02) than RS cells.
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Figure 11.
Percentages of presynaptic fields generating
excitatory (A) and inhibitory
(B) inputs onto layer V pyramidal cells in
relationship to layer- and column-dependent location: IB cells
(black columns; n = 7) and RS cells
(gray columns; n = 8).
C, Ratio of fields generating EPSPs to fields generating
IPSPs in IB cells and RS cells. Data are mean ± SD.
Asterisks indicate significant differences at
p < 0.05 (*) and p < 0.01(**)
levels.
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Inhibitory inputs as well originated from layer II-VI (Fig.
11B). Intracolumnar inhibitory inputs onto IB cells
could be demonstrated from layers II/III and IV as well as V and
amounted to <2%. Weak transcolumnar inhibitory inputs originated only
from layer V. On the other hand, RS cells received significantly more
intracolumnar inhibitory inputs from fields in layers II/III (7.5%;
p < 0.001, t test) and V (8.3%;
p = 0.003). In layer II/III, inhibitory inputs were
often aligned to the apical dendrite of the RS cells. Occasionally RS
cells also received distinct inhibitory inputs from fields in layers IV
and VI, but because of their high variability these values were not
significantly different compared with the IB cells. The differences in
the strength of the inhibitory and excitatory synaptic inputs between
RS and IB cells became even more apparent after the ratio was
calculated between fields providing excitatory and fields providing
inhibitory inputs for both cell types (Fig. 11C). IB cells
revealed on average a 10-fold higher ratio of excitatory to inhibitory
inputs than RS cells (IB: 84 ± 55, n = 7; RS:
8 ± 2, n = 8; p < 0.001, ANOVA).
| |
DISCUSSION |
In the present study we combined whole-cell recordings with
biocytin-containing electrodes and local photolysis of caged glutamate to study the intracortical synaptic inputs onto layer V pyramidal cells
in rat barrel cortex in vitro. We were able to show that the
excitatory projection neurons of layer V, i.e., intrinsically burst
spiking and regular spiking pyramidal cells, each possess a number of
unique connectional properties. Remarkable are the previously
undescribed prominent excitatory inputs from layers IV and VI that were
stronger for IB than for RS cells, intracolumnarly and transcolumnarly.
Furthermore, we could directly show the laminar origins and
distribution of inhibitory inputs, which were much more prominent in RS
than in IB cells.
Technical considerations
We have shown previously with extracellular recording techniques
that long-term stable responses can be obtained by local release of
(gamma-CNB)-caged L-glutamic acid in rat cortical slices (Kötter et al., 1998). Here, we focused on layer V pyramidal neurons and performed a number of important control experiments to
evaluate our setup for analyses at the single-cell level. We reduced
the intensity of the UV flash and the size of the
activated area to reliably elicit an action potential only during
stimulation of perisomatic fields restricted to 50-100 µm from the
soma of the cell, thus providing a layer-specific resolution. For that purpose, we performed control recordings from neurons in all
cell-containing cortical layers. Furthermore, we defined a criterion to
differentiate between synaptic responses resulting from suprathreshold
activation of presynaptic neurons and direct nonsynaptic stimulation
caused by activation of glutamate receptors on the recorded cell.
Recordings from the same cell were performed in normal ACSF as well as
in low Ca2+/high
Mg2+-containing solution to block synaptic
transmission to allow comparison of the spatial distribution of the
different types of evoked activity. The delay-to-onset times were
longer for the synaptic responses because of long and variably sized
action potential latencies in the presynaptic neurons (Katz and Dalva,
1994; Molnar and Nadler, 1999). Consequently, we can interpret the
layer-specific spatial distribution of connected neurons but not the
temporal properties of their input. Therefore, the stimulation
procedure as well as the data analysis allow us to construct detailed
maps of neuronal locations giving rise to intracortical synaptic inputs
onto identified layer V pyramidal cells. In these maps, analysis of
percentages of sites with detectable PSPs turned out to be more
sensitive to cell type-specific differences than analysis of EPSP
integrals. The latter showed a higher variability resulting from
a large range of values for each single cell. This variability of
synaptic transmission may result partially from paired-pulse
facilitation and depression (Thomson, 1997).
Structural properties and firing patterns of layer V
pyramidal cells
In agreement with previous reports, we found a significant
correlation between the morphology of the cell and its intrinsic firing
pattern. Layer V cells with a large soma, a thick apical trunk,
and a rich apical dendritic tree responded to injection of a
suprathreshold current pulse with a burst of action potentials (Chagnac-Amitai et al., 1990; Larkman and Mason, 1990) or at least a
doublet (Schwindt et al., 1997). In contrast, all regular-spiking cells
were characterized by a smaller soma, a thinner apical trunk, and a
more restricted dendritic branching pattern. In addition to confirming
these properties of different layer V pyramidal cells, our results
demonstrate that these two cell types also differ in their
intracortical synaptic inputs.
Intracolumnar and transcolumnar inputs onto layer V
pyramidal cells
The topographic maps show extensive excitatory and inhibitory
synaptic inputs from neurons located in layers II-VI onto layer V
pyramidal cells. The weak synaptic inhibition of IB neurons, mainly
derived from interneurons located relatively close to the recorded
cell, as demonstrated here, is in agreement with previous electrophysiological investigations (Chagnac-Amitai and Connors, 1989a;
Chagnac-Amitai et al., 1990; Nicoll et al., 1996). The more pronounced
inhibitory inputs onto RS cells originated mainly from layers II/III
and V of the same column (Nicoll et al., 1996), as well as from layer V
of the adjacent column (Salin and Prince, 1996). Inhibitory
interneurons in layer IV provided only a weak synaptic input in
accordance with their highly restricted axonal arbors (Harris and
Woolsey, 1983). These data clearly demonstrate that IB cells are under
less inhibitory control than RS neurons. Therefore IB cells should be
capable of distributing their activity reliably within a larger
neuronal network.
In our experiments, excitatory inputs from layer II/III, which are
supposed to be the main extralaminar source of excitatory input onto
layer V pyramidal cells (Thomson and Deuchars, 1997; Reyes and Sakmann,
1999), were comparatively weak and spatially restricted. However,
referring to our control experiments (see Materials and
Methods), for some cells in layer II/III our stimulation may have been
too weak to elicit action potentials. One possible reason for this
could be that layer II/III pyramidal cells have lower resting membrane
potentials than, for example, layer V pyramidal cells and require
higher depolarization amplitudes to reach threshold (Mason and Larkman,
1990).
We expected excitatory inputs originating from the granular layer to be
weak, because (1) anatomical studies have shown relatively sparse layer
IV to V projections (Gilbert and Wiesel, 1983; Callaway and Wiser,
1996; Lübke et al., 2000), and (2) because physiological studies
have supported a sequential intracortical pathway leading from layer IV
to layer II/III and finally to layer V (Armstrong-James et al., 1992;
Laaris et al., 2000). In contrast, our results clearly show strong,
patchy inputs from layer IV within the same and adjacent column for
both cell types. Such strong excitatory influences of layer IV onto
layer V were recently described at the population level in a study of
functional connectivity in the rat barrel cortex (Staiger et al.,
2000). Here we show that in addition to the oligosynaptic pathway
mentioned above, a strong monosynaptic input also exists. According to
its spatial pattern, this input was probably provided by clusters of
strongly coupled spiny neurons in layer IV (Feldmeyer et al., 1999),
with most of the synaptic contacts onto layer V pyramidal cells located
in or near the granular layer (Lübke et al., 2000). The possible
occurrence of synaptic contacts between axons of spiny stellate neurons
and apical dendrites of layer V pyramidal cells extending through
granular and supragranular layers might resolve the discrepancy of an
anatomically sparse but functionally potent layer IV to V input.
The bulk of excitatory synaptic inputs onto IB cells was provided from
neurons located in infragranular layers of the same and adjacent
column. These dominant excitatory inputs are probably mediated by the
extensive intralaminar coupling between layer V IB cells
(Chagnac-Amitai et al., 1990) and ascending collaterals arising from
layer VI spiny neurons (Zhang and Deschenes, 1997). Photostimulation of
fields in layer VI caused strong and widespread excitatory responses in
IB cells, whereas RS neurons received only moderate inputs from this
layer. This finding indicates a strong but cell type-dependent
interaction between the two major cortical output layers V and VI
(Deschenes et al., 1998). For RS cells, inputs from layer V were more
pronounced than from layer VI, indicating a strong coupling between RS
cells and other pyramidal cells within layer V.
Functional implications
The present study demonstrates cell type-specific differences in
functional connectivity for the two major types of excitatory cells in
layer V of the rat barrel cortex. Extensive intracolumnar and
transcolumnar excitatory inputs onto IB cells are provided by neurons
from all layers and accompanied by only weak inhibitory control. Under
physiological conditions, IB cells may effectively integrate inputs
from several cortical columns. Ensembles of these cells could possibly
function as intracortical pacemakers and mediate widespread synchronous
activity with characteristic rhythmic properties (Chagnac-Amitai and
Connors, 1989b; Silva et al., 1991; Flint and Connors, 1996). Such
rhythms are considered to be instrumental in the integration of
different features of a distinct sensory percept (Singer, 1993) and
have been shown to exist in the barrel cortex as well (Barth and Di,
1991; Jones and Barth, 1997). According to our data, IB cells may not
only synchronize cortical circuits, but may also boost cortical outputs
to subcortical and feedback circuits (Ahissar et al., 2000). Finally,
the strong and widespread intracortical interactions, the weak
inhibitory control, and the burst discharge may promote the initiation
and propagation of epileptiform discharge. Therefore, layer V IB cells
could play a critical role in synchronizing cortical modules under
physiological as well as pathophysiological conditions (Connors and
Amitai, 1993).
The complex excitatory and inhibitory intracolumnar control of RS cells
obviously provides them with different information-processing capabilities. By feeding back inputs to the supragranular layers, these
cells could participate in filtering sensory information by decoding
the physical properties of tactile stimuli derived from the respective
"principal" whisker (Simons, 1978, 1995). How these
"intracolumnar RS" and "transcolumnar IB" circuits interact remains an important issue for further investigations.
In conclusion, our analyses revealed the following aspects of layer V
circuitry organization. (1) The specific pattern of functional
connectivity of layer V pyramidal cells correlates with the
morphological and electrophysiological properties of these neurons. (2)
Both IB and RS cells receive excitatory synaptic inputs from all
cortical layers, in a more or less homogenous fashion from layers V and
VI, whereas inputs from layers IV and II/III show a patchy pattern.
Inputs from layer VI are significantly stronger for IB than for RS
pyramidal cells. (3) IB cells receive only a weak inhibitory input,
mainly originating locally from within layer V. In contrast, the more
extensive inhibitory inputs onto RS cells originate primarily from
layers II/III and V of the same column and from layer V of the adjacent column.
| |
FOOTNOTES |
Received Jan. 18, 2001; revised March 5, 2001; accepted March 6, 2001.
This study was supported by the Gesellschaft der Freunde und Foerderer
der Heinrich-Heine-Universitaet, Duesseldorf, the C. & O. Vogt-Institut
fuer Hirnforschung GmbH, the Gertrud Reemtsma Stiftung, and Deutsche
Forschungsgemeinschaft Grant Lu 375/3-2 to H.J.L. We thank U. Opfermann-Emmerich for skilled technical assistance.
Correspondence should be addressed to Dirk Schubert, Institute of
Neurophysiology, Heinrich-Heine-University Duesseldorf, POB 101007, D-40001 Duesseldorf, Germany. E-mail:
schubd{at}uni-duesseldorf.de.
| |
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INTRODUCTION
