 |
 Previous Article | Next Article 
The Journal of Neuroscience, July 15, 1999, 19(14):6191-6199
Interactions between Hippocampus and Medial Septum during Sharp
Waves and Theta Oscillation in the Behaving Rat
George
Dragoi1,
Daniel
Carpi1,
Michael
Recce2,
Jozsef
Csicsvari1, and
György
Buzsáki1
1 Center for Molecular and Behavioral Neuroscience,
Rutgers, The State University of New Jersey, Newark, New Jersey 07102, and 2 Department of Computer Science, New Jersey Institute
of Technology, Newark, NJ 07102
 |
ABSTRACT |
The medial septal region and the hippocampus are connected
reciprocally via GABAergic neurons, but the physiological role of this
loop is still not well understood. In an attempt to reveal the
physiological effects of the hippocamposeptal GABAergic projection, we
cross-correlated hippocampal sharp wave (SPW) ripples or theta activity and extracellular units recorded in the medial septum and
diagonal band of Broca (MSDB) in freely moving rats. The majority of
single MSDB cells (60%) were significantly suppressed during SPWs.
Most cells inhibited during SPW (80%) fired rhythmically and
phase-locked to the negative peak of the CA1 pyramidal layer theta
waves. Because both SPW and the negative peak of local theta waves
correspond to the maximum discharge probability of CA1 pyramidal cells
and interneuron classes, the findings indicate that the activity of
medial septal neurons can be negatively (during SPW) or positively
(during theta waves) correlated with the activity of hippocampal
interneurons. We hypothesize that the functional coupling between
medial septal neurons and hippocampal interneurons varies in a
state-dependent manner.
Key words:
EEG; GABAergic neurons; interneurons; ripples; cholinergic system; lateral septum
| |
INTRODUCTION |
The septal region and the
hippocampus are connected reciprocally (Raisman, 1966 ). The two major
components of the septohippocampal projection consist of cholinergic
and GABAergic cells (Shute and Lewis, 1963; Lewis et al., 1967;
Köhler et al., 1984), residing in the medial septum and the
diagonal band of Broca (MSDB). The cholinergic projection terminates on
all types of hippocampal cells (Shute and Lewis, 1966; Frotscher and
Leranth, 1985; Freund and Antal, 1988), whereas septal GABAergic
neurons specifically innervate GABAergic interneurons (Freund and
Antal, 1988; Gulyás et al., 1991). A subpopulation of the target
GABAergic cells, in turn, projects back to the MSDB and preferentially
innervates the GABAergic population (Alonso and Köhler, 1982;
Gaykema et al., 1991; Tóth et al., 1993). The hippocamposeptally
projecting neurons contain the calcium binding protein calbindin
(Tóth and Freund, 1992; Tóth et al., 1993). Hippocampal
pyramidal cells project only to the lateral septum (Alonso and
Köhler, 1982; Leranth and Frotscher, 1989). The main
projection of the lateral septum is subcortical, and axon collaterals
to the MSDB are either absent or very sparse (Gulyás et al.,
1991; Staiger and Nürnberger, 1991; Leranth et al., 1992).
Therefore, the major reciprocal communication between the septum and
hippocampus is mediated by the MSDB and hippocampal GABAergic cells.
The functional role of this reciprocal hippocamposeptal GABAergic loop
is not understood.
The hippocampal formation displays two behaviorally and physiologically
distinct patterns: theta waves and sharp waves (SPWs). The importance
of the septum in hippocampal theta generation has been documented by
numerous experiments. In an early formulation, neurons in the MSDB have
been assumed to play the role of a pacemaker by providing a coherent
and rhythmic drive to the hippocampus (Green and Arduini, 1954; Petsche
et al., 1962; Stumpf et al., 1962; Winson, 1978; Andersen et al.,
1979). Subsequent studies have shown that MSDB GABAergic cells have the
intrinsic propensity to oscillate at theta frequency (Serafin et al.,
1996) and suggested that a coordinated output of the GABAergic and
cholinergic populations is responsible for phase-locking hippocampal
neurons (Stewart and Fox, 1989; Lee et al., 1994; Brazhnik and Fox,
1997). In contrast, other studies could not confirm the hypothesis that
either the putative cholinergic or GABAergic MSDB neurons discharge
coherently during the theta cycle (Gaztelu and Buño, 1982;
Stewart and Fox, 1989, 1990; King et al., 1998). Two major
technical problems have hampered progress in this area of research. The
first is the lack of unambiguous criteria for the identification of
neuronal types from the extracellularly recorded spike patterns and the
lack of histological identification of intracellularly studied neurons in acute experiments. The second problem is to isolate the contribution of the participating members in multiple loops (Vertes and Kocsis, 1997).
Theta rhythm is generated by a consortium of various pathways and
mechanisms. In contrast, SPW bursts are known to emerge in the
recurrent collateral system of CA3 pyramidal cells (Buzsáki et
al., 1983). The synchronous discharge of pyramidal cells induces high
frequency and coherent discharge of the target interneurons, including
the calbindin-immunoreactive subclass, with axonal projection to the
MSDB (Tóth and Freund, 1992). We reasoned, therefore, that by
studying the correlation between hippocampal SPWs and MSDB neuronal
activity, we can assess the unidirectional effect of hippocampal
interneurons on MSDB neuronal populations. In addition, previous
research has established that both pyramidal neurons and various
classes of interneurons display their highest discharge probability
around the negative peak of theta waves in the CA1 pyramidal layer (Fox
et al., 1986; Skaggs et al., 1996; Csicsvari et al., 1999).
Using both SPWs and theta oscillations as reference signals for the
maximum discharge probability of interneurons, we examined their impact
on the activity of MSDB neurons in these two respective states.
| |
MATERIALS AND METHODS |
Animals and surgery. Ten adult male Sprague Dawley
rats (weighting 300-500 gm) were anesthetized with a mixture (4 ml/kg) of ketamine (25 mg/ml), xylazine (1.3 mg/ml), and acepromazine (0.25 mg/ml) administered intramuscularly, following National Institutes of
Health guidelines. Tungsten high-impedance electrodes (0.5-1 M ;
Micro Probe Inc., MD) were mounted on movable drives and used to record
the unit activity in the MSDB area. Each complete turn of the
microdrive moved the electrode 0.3 mm axially. A hole (1 mm in
diameter) was drilled above the septal area in the midline. After
cutting the dura mater, the sagittal sinus was gently moved aside, and
the tungsten electrode was lowered into the midline, ~1 mm above the
medial septum [anteroposterior (AP), 0-0.7; lateral (L), 0; ventral
(V), 5], according to the atlas coordinates of Paxinos and
Watson (1997). In one rat, two such microdrives were used, one for
recording from the MSDB and the other one from the lateral septum. The
hippocampal recording electrodes were constructed from 50-µm-diameter
stainless steel wire coated with insulation (California Fine Wire,
Grover Beach, CA). Two of these wires, with 250 µm vertical and 300 µm horizontal distance between their tips, were mounted on the same
type of microdrive as in the high-impedance electrode. These electrodes
were unilaterally implanted through holes drilled above the dorsal
hippocampus (AP, 4; L, 2.5; V, 1.5). In addition, a pair of stainless
steel wires (100 µm in diameter) with 0.5 mm vertical tip separation
was placed in the fimbria (AP,  1.3; L, 1; V, 3.8) to stimulate the
commissural afferents to the CA1 region. The microdrives, as well as
the stimulating electrodes, were fixed to the skull with dental
acrylic. Two stainless steel screws driven into the bone above the
cerebellum served as reference and ground electrodes. Two additional
screws in the frontal bone acted as anchors. After the operation, the
rats were kept one to a cage, weighed, and inspected daily. Recording
began after 1 week of recovery.
Recording and data analysis. The wire electrodes were
lowered into the hippocampus until the CA1 pyramidal layer was
identified. Positioning of the hippocampal electrodes was aided by the
response evoked by commissural stimulation and by the presence of field ripples (200 Hz oscillations) associated with unit activity (Ylinen et
al., 1995). After stable recording from the pyramidal cell layer, the
tungsten electrode was moved into the MSDB until discriminable septal
units were recorded. Recordings were performed in the home cage while
the rat was sleeping. Rapid eye movement sleep (REM) was
distinguished from slow-wave sleep (SWS) by the presence of continuous theta waves and immobile sleeping posture. The duration of
recording sessions varied between 5 and 55 min. The electrical signals
were amplified, bandpass filtered (1 Hz to 5 kHz; model 12-64
channels; Grass Instruments, Quincy, MA), digitized with 12-bit
resolution at 10 or 20 kHz (ISC-16 analog-to-digital converter; RC
Electronics, Santa Barbara, CA), and recorded continuously using a 486 personal computer. The data were stored on 4 mm digital audio
tapes and analyzed off-line. To detect the unit activity, the
wide-band recorded signals were digitally high-pass filtered (800 Hz-5
kHz). Septal and hippocampal units were identified and isolated from
the extracted spikes based on amplitudes and wave shapes using a manual
cluster cutting method, as described recently (Csicsvari et al., 1998).
Units showing a refractory period in the autocorrelogram larger than 2 msec were further considered as single units. The beginning, middle,
and end of the hippocampal ripple episodes were detected by applying an
amplitude threshold to the previously bandpass (150-250 Hz) filtered
hippocampal EEG data. Hippocampal theta epochs were automatically
identified by using the theta/delta power ratio, whereas the individual
theta cycles were detected after bandpass (5-28 Hz) filtering the
recorded data (Csicsvari et al., 1998). For analysis, 15-600 sec of
theta epochs and 100-1500 successive SPW events were used. The middle of the ripples and the negative peak of the theta waves were
subsequently used as zero reference points to compute unit-to-ripple
cross-correlograms and unit-to-theta phase histograms (Csicsvari et
al., 1999). Autocorrelation and cross-correlation functions were
calculated separately during theta waves, sharp waves, and between
sharp wave bursts. Because the number of action potentials used for the
construction of autocorrelograms and cross-correlograms varied from
cell to cell, the histograms were normalized by dividing each bin by
the number of reference events. Thus, the histograms reflect discharge
probabilities. The method for constructing phase histograms have been
described previously (Csicsvari et al., 1999). In short, each spike was assigned to a given phase (bin size of 20°) of the normalized field
cycle (ripple-theta). To reduce bin-border variability, the action
potential times were substituted with a Gaussian kernel function.
Histograms with mean bin value of less than five spikes were excluded
from the analysis. Theta and ripple averages were obtained by averaging
filtered signals, using the positive peaks of the ripples waves and the
negative peaks of the theta cycle as the zero reference.
Histology. After the completion of the experiments, the rats
were deeply anesthetized with a high dose of Nembutal (100 mg/kg, i.p.). The electrodes remained in situ, and the rats were
perfused transcardially with saline, followed by a phosphate-buffered
(PB) (0.1 M) fixative (4% paraformaldehyde, 0.15% picric
acid, and 0.05% glutaraldehyde). The brains were removed from the
skull, blocks of the MSDB and hippocampus were dissected, and
80-µm-thick sections were cut on a vibratome. The brains of five rats
were stained with the Nissl method, and the remaining five were
processed for parvalbumin or choline acetyltransferase (ChAT)
immunostaining on alternate sections, as follows. After washing, the
brain slices were treated with 0.5% Triton X-100 diluted in 0.1 M PB, pH 7.4. Next, the sections were incubated
overnight in the primary antisera, rabbit anti-parvalbumin (1:1500) or
rat anti-ChAT (1:10; Boehringer Mannheim, Mannheim, Germany),
followed by the secondary antibodies (biotinylated anti-rabbit IgG;
1:200; Vector Laboratories, Burlingame, CA) and anti-rat Ig-biotin
F(ab')2 fragment (1:200; Boehringer Mannheim) for 2 hr,
followed by avidin-biotin-horseradish peroxidase complex (1.5 hr;
1:200; Vector Laboratories). The immunoperoxidase reaction was
developed using 3,3'-diaminobenzidine (1:200; Sigma, St. Louis, MO).
The brain sections were dried on gelatin-coated slides, dehydrated, and
covered with Depex for light microscopy. A single septal track was made
per animal, and it was recovered in all animals. Only rats with tracks
that undoubtedly penetrated parvalbumin- and/or ChAT-rich areas within
the borders of the MS/DB were considered for further analysis.
| |
RESULTS |
In 7 of the 10 operated rats, the recording electrode passed
through the MSDB, as verified by the histological analysis (Fig. 1). Only data from these rats are
included in this report. The position of the recorded unit was
estimated by histological verification of the tip of the electrode and
the number of turns of the microdrive. A total of 25 putative single
MSDB units that fired during both REM and SWS were analyzed further.
From each recording site, only the most well isolated single unit was
processed (Fig. 2). Although the
refractory test assured us that the units included in the analysis were
derived from a single cell, smaller amplitude units, generated by the
same neuron, might have been lost. Although this omission error does
not affect the main conclusion of our findings, it may affect the
firing frequencies reported below.
View larger version (70K):
[in this window]
[in a new window]
|
Figure 1.
Location of the recorded units in MSDB.
Lines indicate electrode tracks.
Asterisks, Estimated location of recording sites.
Image, ChAT immunostaining illustrating the recording
track. Inset, Parvalbumin immunostaining of an adjacent
section; the arrow points to the midline.
Arrowheads mark the tracks of the same electrode on
diagram and histological sections. Numbers represent
distance (in millimeters) from bregma. aca,
Anterior commissure; cc, corpus callosum;
2n, optic nerve. Anatomical diagrams adapted from
Paxinos and Watson (1997).
|
|
View larger version (29K):
[in this window]
[in a new window]
|
Figure 2.
Hippocampal field and septal unit activity during
theta waves (A-C) and SPW ripples
(D-F). A, D,
Wide-band (1 Hz to 5 kHz) recording of a theta oscillation
(A) and ripples (D) from
CA1 pyramidal layer. B, Filtered derivative (14 Hz
low-pass) of A. E, Filtered derivative
(150-250 Hz) of D. C, F,
Filtered MSDB unit activity (0.8-5 kHz) recorded simultaneously with
the hippocampal traces. Note rhythmic multiple-unit discharge in MSDB
during theta. Note also the apparent lack of the MSDB unit activity
during hippocampal ripples.
|
|
Discharge patterns of MSDB cells during theta oscillation
Because nearly all available information regarding the firing
patterns of MSDB neurons has been collected during hippocampal theta
activity, we first examined the phase and amplitude modulation of the
recorded cells during the theta cycle. The cells were divided into
three major groups according to previously established criteria (Gaztelu and Buño, 1982; Alonso et al., 1987; King et al., 1998). All type 1 cells (n = 18) showed rhythmicity in their
autocorrelograms and fired phase-locked to hippocampal theta. Type 1A
subgroup (n = 2; firing rates, 90.1 and 48.8 Hz; peak
intraburst firing rates, 500.5 and 416.6 Hz, respectively) emitted more
than five spikes during each theta cycle. Theta-associated repeating
bursts were revealed as a small secondary peak at 85-95 msec in the
interspike (ISI) histogram. Type 1B cells (n = 6; mean
firing rate, 21.5 ± 7.4 Hz; peak intraburst frequency, 275.6 ± 66.7 Hz) fired shorter bursts (two to four spikes) per theta wave
reflected as a secondary peak at 100-125 msec in the ISI histogram.
Type 1C neurons (n = 10; firing rate, 20.5 ± 13.8 Hz) did not show a clear bursting behavior, but their ISI histograms
occasionally revealed theta-associated rhythmicity. Type 2 cells
(n = 5; firing rate, 16.28 ± 8.5 Hz) showed no
rhythmicity in their autocorrelograms but fired phase-locked to the
hippocampal theta. Type 3 cells (n = 2; firing rates,
2.3 and 2.7 Hz) showed no theta-related rhythmicity and were not
phase-locked to the theta cycle.
Activity of MSDB neurons during SPW ripples
SPWs in the CA1 stratum radiatum are associated with synchronous
cell discharge of both pyramidal cells and interneurons. Concurrent
with the SPW, a fast-field oscillation (200 Hz ripple) is present in
the pyramidal layer (Buzsáki et al., 1992). Using the
ripples as a reference event, peri-ripple unit firing probability histograms were constructed. The histograms were normalized by dividing
the cumulative bin events by the number of ripples. At least 100 SPW
events and 3000 spikes were used for the construction of a histogram.
The comparison between hippocampal ripples and discharge of MSDB
neurons revealed that none of the putative single units increased its
firing frequency during SPW ripples. On the other hand, the discharge
probability of many of the recorded units decreased selectively during
SPW ripples. The SPW concurrent suppression of neuronal discharge in a
representative type 1 MSDB neuron is shown in Figure
3E. The neuron displayed
highly rhythmic activity during hippocampal theta activity, as shown by
the theta-unit phase histogram and its autocorrelation function and ISI
histogram (Fig. 3A-C). During SPW ripples, the
multiple-unit activity recorded from the CA1 pyramidal layer increased
several-fold (Fig. 3D). Concurrent with the increased
activity of hippocampal neurons, the discharge probability of the MSDB
unit decreased substantially (Fig. 3E).
View larger version (33K):
[in this window]
[in a new window]
|
Figure 3.
Discharge correlates of a rhythmically bursting
MSDB single unit (type 1B) during hippocampal theta, nontheta, and
SPWs. Nontheta periods included events during and in between SPWs.
A, Autocorrelogram of the MSDB unit during hippocampal
theta (black) and nontheta (gray)
epochs. Insets, ISI histograms during theta and
nontheta. Note high degree of rhythmicity during theta.
B, Cross-correlogram between MSDB unit and negative
peaks of theta waves and averaged theta field (gray
line). C, Theta phase histogram of the MSDB
single unit. Note that the MSDB unit was phase-locked to the negative
peak of theta, recorded from the CA1 pyramidal layer. D,
E, Cross-correlogram between hippocampal ripple
(gray line) and locally recorded multiple-unit
activity (D) and MSDB unit
(E). Note decreased MSDB discharge during the
ripple. Values on the y-axes represent firing
probabilities (except for ISIs).
|
|
To quantify this relationship between hippocampal SPW ripples and MSDB
unit activity, the firing probability around the ripple peak (±50 msec
from the peak) was compared with the baseline discharge of the putative
single neurons. Baseline discharge was calculated from the firing rate
in the intervals between 250 to 75 msec and 75 to 250 msec. The
firing rate of a given neuron was arbitrarily judged as suppressed when
the value of at least three neighboring 5 msec bins around the ripple
peak was more than two SDs below the baseline probability.
Fifteen of the 25 putative single cells were significantly inhibited
during the occurrence of hippocampal SPWs (Fig.
4). For comparison, the activity of the
MSDB neurons is displayed together with SPW-related discharge of
pyramidal cells and hippocampal interneurons from a previous study,
recorded under identical conditions (Fig.
4A,B) (Csicsvari et al., 1999). The
length of significant discharge suppression varied from three 5 msec
bins (our criteria) to 11 consecutive bins (55 msec). Of the inhibited
cells, 14 were type 1 (93.3%), 1 belonged to the type 2 category
(6.7%), and none was from the type 3 group (0%). The distribution of
significantly suppressed cells in the various cell groups, rhythmic
(type 1) versus nonrhythmic (types 2 and 3), differed significantly
(p < 0.005;  2 test of
independence). The remaining cells did not show significant suppression
according to our criteria. Nevertheless, the grand average of the
cross-correlograms of these neurons also showed some suppression of
neuronal firing at around the center of the SPW burst.
View larger version (32K):
[in this window]
[in a new window]
|
Figure 4.
Firing rates of MSDB neurons are suppressed during
hippocampal SPWs. A, Average field ripple wave.
B-E, Discharge probabilities of hippocampal and MSDB
neurons during hippocampal SPW-associated ripples. B,
Average firing probability of different neuronal subgroups recorded
from the CA1 area of the hippocampus. Note almost threefold increase in
discharge probability of the interneurons in the alveus/stratum oriens
and in the pyramidal layer during ripples (data replicated from
Csicsvari et al., 1999). C, Average peri-ripple firing
probability histogram for MSDB cells, which showed a significant
reduction of discharge probability during SPW ripples
(n = 13) (see Materials and Methods). Type 1A
neurons are not included (n = 2). D,
Peri-ripple firing probability histogram for MSDB cells, which failed
to show a significant ripple-related reduction of discharge probability
(n = 10). Error bars indicate SE.
E, Peri-ripple firing probability histogram of a type 1A
cell. Note the early inhibition and the maintenance of a theta-like
oscillation during ripple-centered epochs. Peak of the hippocampal
ripple, 0 msec. Histograms in C-E were normalized to
the baseline firing probability calculated from 250 to 150 msec.
int(p), Interneurons recorded from the pyramidal layer;
int(a/o), Interneurons from the alveus and stratum
oriens; pyr, CA1 pyramidal neurons.
|
|
Two of the 15 SPW-suppressed neurons, showing the best rhythmic theta
modulation (type 1A) (Figs.
5E,F,
6E), continued to display theta rhythmicity during slow-wave sleep (Fig.
5B,C) (Barrenechea et al., 1995;
Brazhnik and Fox, 1997). One of them was recorded simultaneously with a
unit from the lateral septum (Fig. 5D) monitored through a
second electrode. Whereas the lateral septal unit showed a clear SPW
ripple-associated increase in its discharge pattern (Fig.
5A) (Carpi et al., 1997), the medial septal unit continued to display rhythmicity, as judged by its autocorrelogram (Fig. 5C). The burst-repeating frequency, however, was somewhat
faster in the absence of theta (110 msec) than during theta (140 msec).
View larger version (21K):
[in this window]
[in a new window]
|
Figure 5.
Simultaneous recording of unit activity in MSDB
and lateral septum. A, B,
Cross-correlograms between hippocampal ripple (time 0) and lateral
septum (LS) (A) and MSDB
(B) units. Note increased discharge of lateral
septum unit during ripples. Histograms were normalized to the
baseline firing probability calculated from 200 to 100 msec.
C, Autocorrelogram of the MSDB unit during SPW.
D-F, Cross-correlogram between theta waves and lateral
septum (D) and MSDB (E)
units. F, MSDB autocorrelogram during theta. Note theta
phase-related discharge of both lateral septum and MSDB units. Note
also the persistence of theta rhythmicity of the MSDB unit during
ripple epochs. Arrows in C and
D indicate rhythmic average spike intervals.
|
|
View larger version (17K):
[in this window]
[in a new window]
|
Figure 6.
Average phase distribution of hippocampal and MSDB
units in relation to the CA1 pyramidal layer theta. A,
Average theta field wave. Two theta cycles are shown to facilitate
comparison. Dashed vertical lines mark the negative peak
of hippocampal theta. B, Average phase distribution of
different CA1 cell populations. Note maximum discharge probability of
pyramidal layer [int(p)] interneurons and
alveus/stratum oriens [int(a/o)] interneurons just
before and at the peak of the local theta, respectively (data
replicated from Csicsvari et al., 1999). C,
Theta-related discharge probability of MSDB neurons that were
significantly suppressed during SPWs. D, Theta phase
discharge of MSDB neurons that were not significantly suppressed during
SPW. Error bars indicate SE. E, Phase histograms of the
two type 1A cells. Note the ~90° phase difference compared with the
cells shown in C.
|
|
Population phase-locking of MSDB neurons to the theta cycle
Cross-correlation between MSDB unit activity and hippocampal theta
waves, derived from the CA1 pyramidal layer, revealed individual variability in the preferred theta phase of units (compare Figs. 3B,C, 5E). Although the
chemical nature or connectivity of the recorded MSDB neurons could not
be revealed in the present study, we used the SPW-induced suppression
of firing rate as an independent measure for grouping MSDB neurons. As
Figure 6C shows, MSDB neurons, which were significantly
suppressed during SPW (Fig. 4C), were phase-locked to the
negative part of the theta waves recorded from the CA1 pyramidal layer.
Thus, this subgroup of neurons showed a phase-coherent population
synchrony relative to the theta cycle. The maximum probability of their
discharge corresponded to the maximum discharge of interneurons located
in both the pyramidal layer and alveus/stratum oriens (Fig.
6A,B; Csicsvari et al., 1999).
Thus, in contrast to what is observed during SPW, hippocampal interneurons and a subgroup of MSDB neurons discharge synchronously during theta. The discharge relationship of the two type 1A neurons to
theta waves are shown separately (Fig. 6E). These
were the only SPW-suppressed MSDB neurons whose discharge probability
coincided with the positive portion of the CA1 pyramidal layer theta
waves. The remaining 10 neurons discharged (SPW-unrelated) at a maximum rate on the positive-going phase of the theta cycle (Fig.
6D).
| |
DISCUSSION |
The observations of the present experiment are that (1) a
concerted discharge of hippocampal neurons during the SPW burst is
associated with a concurrent suppression of discharge activity of most
MSDB neurons, and (2) the maximum discharge of the SPW-inhibited MSDB
neurons corresponded to the maximum discharge of CA1 interneurons during theta activity. These findings indicate that the physiological relationship between populations of MSDB and hippocampal neurons varies
as a function of behavior.
Suppression of MSDB neurons during hippocampal SPWs
Because SPWs are generated by the intrinsic circuitry of the
hippocampus, correlation of MSDB neurons with this physiological pattern allowed for the direct investigation of the hippocampal influence on the MSDB neurons. Most MSDB neurons were suppressed during
SPW ripples and none of the cells showed SPW-associated discharge in
their firing probability. Although it is likely that both cholinergic
and GABAergic neurons were sampled by our recordings, the anatomical
identity of our cells remained undisclosed.
The hippocampal projection to MSDB derives from GABAergic interneurons
of the CA3 and CA1 regions (Alonso and Köhler, 1982; Gaykema et
al., 1991; Tóth and Freund, 1992; Tóth et al., 1993). The
hippocampofugal projection terminates mostly on the GABAergic population of the MSDB, but synapses on cholinergic cells were also
noted (Tóth et al., 1993). The intra-MSDB synaptic organization among the various neuronal types is not known, but it has been assumed
that MSDB GABAergic cells give off local collaterals and innervate
neighboring cholinergic cells (Leranth and Frotscher, 1989; Van
der Zee and Luiten, 1994). In light of these anatomical observations,
one would expect that SPW-mediated suppression of MSDB neurons should
relieve the inhibition these neurons may exert on cholinergic neurons.
If this were the case, one may expect to find that at least some MSDB
neurons increased their discharge rate during SPW. This was not found
to be the case, however. Our physiological observations, therefore,
suggest that intraseptal GABAergic innervation of other types of MSDB
cells is considerably weaker than the concerted effect of hippocampal
GABAergic inhibition of MSDB neurons. It should be noted that the
activity of a subgroup of hippocampal interneurons ("anti-SPW"
cells) (Csicsvari et al., 1999) are also suppressed during SPWs. It
remains to be seen whether hippocampal anti-SPW and MSDB neurons are
innervated by the same GABAergic neurons.
What is the physiological function of the reciprocal inhibitory
innervation between the hippocampus and MSDB during SPWs? Because SPWs
are thought to be initiated by the recurrent collateral system of the
hippocampal CA3 region, suppression of MSDB neurons is likely brought
about by the increased activity of septally projecting GABAergic
hippocampal interneurons. In return, the decreased activity of the
target MSDB cells may have important consequences on the activity of
hippocampal neurons, as well. Decreased firing of MSDB GABAergic
neurons may contribute to the termination of SPW burst by disinhibiting
hippocampal interneurons (Tóth et al., 1997), suggesting a
regulatory negative feedback role for the
hippocampus-MSDB-hippocampus loop. Indeed, after fimbria-fornix
lesion, SPWs are converted into large interictal epileptic-like spikes
associated with hypersynchronous activity of pyramidal cells
(Buzsáki et al., 1989). Furthermore, decreased activity of
cholinergic neurons may affect backpropagation of action potentials in
hippocampal pyramidal cells (Tsubokawa and Ross, 1997) and influence
synaptic plasticity (Magee and Johnston, 1997; Markram et al.,
1997).
The SPW-associated activity of MSDB neurons may also exert an important
effect on the hippocampo-lateral septum-hypothalamus pathway.
GABAergic neurons in the MSDB are believed to innervate the GABAergic
neurons in the lateral septum (Swanson and Cowan, 1979; Staiger and
Nürnberger, 1989; Kiss and Patel, 1991). Decreased inhibition of
the lateral septal cells during SPWs therefore may provide temporal
windows for the hippocampal output to influence hypothalamic targets.
The increased discharge of lateral septal neurons during SPWs is
consistent with this assumption (Carpi et al., 1997).
Contribution of MSDB neurons to the theta rhythm
In agreement with previous studies, we found that neurons in the
MSDB form several functional subgroups: rhythmic neurons phase-locked
to theta, nonrhythmic but phase-locked cells, and a smaller group of
cells that were neither rhythmic nor phase-locked to the hippocampal
theta oscillation (Gaztelu and Buño, 1982; Alonso et al., 1987;
King et al., 1998).
It has been suggested that the rhythmic activity of the MSDB neurons is
causally related to the generation of hippocampal theta activity
(Petsche et al., 1962; Apostol and Creutzfeldt, 1974; Mizumori et al.,
1989; Stewart and Fox, 1990; Smythe et al., 1992; Lee et al., 1994;
Brazhnik and Fox, 1999). On the other hand, the discovery of the
reciprocal circuitry between hippocampal interneurons and MSDB cells
(Alonso and Köhler, 1982; Köhler et al., 1984; Freund and
Antal, 1988; Tóth et al., 1993) suggested that the pattern of
MSDB activity can be affected by the hippocampal output. Early studies
using direct stimulation of the hippocampal output (fimbria) showed
that downstream inputs to the septum can suppress or reset the bursting
activity of MSDB neurons (McLennan and Miller, 1974). Previously, it
was tacitly assumed that the hippocampal effects were mediated mostly
via the lateral septum neurons (McLennan and Miller, 1974, 1976).
However, subsequent anatomical studies revealed that the hypothesized
projection from the lateral septum to the MSDB is either very weak or
nonexistent (Staiger and Nürnberger, 1991; Gulyás et al.,
1991; Leranth et al., 1992). Thus, the main stream of communication
between the MSDB area and the hippocampus is by way of septally
projecting hippocampal interneurons.
SPWs are associated with the maximum discharge of hippocampal pyramidal
cells and the majority of interneurons (Csicsvari et al., 1999). As
suggested above, the increased activity of the septally projecting
interneurons may be responsible for the suppression of MSDB neurons
during SPWs. One might expect that increased discharge of hippocampal
interneurons should continue to suppress the activity of the same MSDB
population during theta oscillation. However, during theta oscillation,
both hippocampal interneurons and the SPW-suppressed MSDB population
discharged maximally on the same phase of theta waves, i.e., in a
positively correlated manner. Assuming that the septally projecting
neurons fired in phase with the remaining population of
alveus/stratum oriens interneurons, the observed phase
relationship indicates that a simple inhibitory mechanism is not
sufficient for the explanation of relationship between these respective
neuronal groups during theta state. The state-dependent relationship
between hippocampal interneurons and MSDB neurons suggests that the
same anatomical pathways are used differentially in different
behavioral states. One possibility is that the availability of
subcortical neurotransmitters determines whether the firing patterns of
hippocampal interneurons and MSDB cells are positively or negatively
correlated. Another possible scenario is that the magnitude of the
excitatory drive on the participating neurons of the GABAergic
septohippocampal loop determines the firing relationship between
hippocampal interneurons and MSDB cells. MSDB neurons may be influenced
by their reciprocal collaterals, by the hippocamposeptal GABAergic
projection and, possibly, by local MSDB GABAergic interneurons (Leranth
et al., 1992; Tóth et al., 1993). Depending on the exact
functional coupling within these multiple inhibitory loops, the firing
frequency of the participating neurons may either increase or decrease
(Freund and Buzsáki, 1996).
Although the SPW-suppressed group represents a functional entity, their
relationship to the anatomical classes of MSDB neurons is not clear. On
the basis of theta phase correlations and the relative magnitude of
theta phase modulation, the findings of Brazhnik and Fox (1999, their
Fig. 5) would suggest that SPW-suppressed neurons correspond to
cholinergic cells and the remaining population to GABAergic neurons.
Consequently, increased activity of MSDB GABAergic projecting cells
would periodically inhibit hippocampal interneurons at theta frequency
(Stuart and Fox, 1990; Lee et al., 1994) and vice versa. A prediction
of this scenario is that GABAergic MSDB neurons should be less affected
by the septally projecting interneurons than the cholinergic ones, in
contrast to the anatomical evidence for the strong hippocampal
innervation of septal GABAergic cells (Tóth et al., 1993).
Another study did not observe a reliable relationship between theta
phase and putative anatomical groups in the MSDB (King et al.,
1998). The strongly phase-locked discharge of hippocampal
interneurons (Ranck, 1973; Buzsáki and Eidelberg, 1983; Fox et
al., 1986; Skaggs et al., 1996; Csicsvari et al., 1999) and the
physiological effectiveness of the septally projecting subgroup, as
shown here, indicate that the hippocamposeptal projection may be
responsible for the phase-locking of nonrhythmic, slower discharging,
putative cholinergic neurons (Griffith and Matthews, 1986; Matthews and
Lee, 1991; King et al., 1998) and/or assist the timing of GABAergic
neurons (X.-J. Wang, personal communication).
| |
FOOTNOTES |
Received March 8, 1999; revised May 3, 1999; accepted May 5, 1999.
This work was supported by National Institutes of Health Grants NS34994
and MH54671. We thank Z. Borhegyi, H. Hirase, C. King, and Z. Nadásdy for help and support and T. F. Freund for his comments on this manuscript.
Correspondence should be addressed to György Buzsáki,
Center for Molecular and Behavioral Neuroscience, Rutgers University, 197 University Avenue, Newark, NJ 07102.
| |
REFERENCES |
-
Alonso A,
Köhler C
(1982)
Evidence for separate projections of hippocampal pyramidal and non-pyramidal neurons to different parts of the septum in the rat brain.
Neurosci Lett
31:209-214[Web of Science][Medline].
-
Alonso A,
Gaztelu JM,
Buño W,
García-Austt E
(1987)
Cross-correlation analysis of septohippocampal neurons during theta-rhythm.
Brain Res
413:135-146[Web of Science][Medline].
-
Andersen P,
Bland BH,
Myhrer T,
Schwartzkroin PA
(1979)
Septohippocampal pathway necessary for dentate theta production.
Brain Res
165:13-22[Web of Science][Medline].
-
Apostol GH,
Creutzfeldt OD
(1974)
Crosscorrelation between the activity of septal units and hippocampal EEG during arousal.
Brain Res
67:65-75[Web of Science][Medline].
-
Barrenechea C,
Pedemonte M,
Nuñez A,
García-Austt E
(1995)
In vivo intracellular recordings of medial septal and diagonal band of Broca neurons: relationships with theta rhythm.
Exp Brain Res
103:31-40[Web of Science][Medline].
-
Brazhnik ES,
Fox SE
(1997)
Intracellular recordings from medial septal neurons during hippocampal theta rhythm.
Exp Brain Res
114:442-453[Web of Science][Medline].
-
Brazhnik ES, Fox SE (1999) Action potentials and relations to
the theta rhythm of medial septal neurons in vivo. Exp
Brain Res, in press.
-
Buzsáki G,
Eidelberg E
(1983)
Phase relations of hippocampal projection cells and interneurons to theta activity in the anesthetized rat.
Brain Res
266:334-339[Web of Science][Medline].
-
Buzsáki G,
Leung LWS,
Vanderwolf CH
(1983)
Cellular bases of hippocampal EEG in the behaving rat.
Brain Res Rev
6:139-171.
-
Buzsáki G,
Ponomareff GL,
Bayardo F,
Ruiz R,
Gage FH
(1989)
Neuronal activity in the subcortically denervated hippocampus: a chronic model for epilepsy.
Neuroscience
28:527-538[Web of Science][Medline].
-
Buzsáki G,
Horváth Z,
Urioste R,
Hetke J,
Wise K
(1992)
High-frequency network oscillation in the hippocampus.
Science
256:1025-1027[Abstract/Free Full Text].
-
Carpi D,
Dragoi G,
Benuck M,
Buzsáki G
(1997)
Neuronal activity of lateral septum during hippocampal theta and sharp waves in the behaving rat.
Soc Neurosci Abstr
23:484.
-
Csicsvari J,
Hirase H,
Czurkó A,
Buzsáki G
(1998)
Reliability and state dependence of pyramidal cell-interneuron synapses in the hippocampus: an ensemble approach in the behaving rat.
Neuron
21:179-189[Web of Science][Medline].
-
Csicsvari J,
Hirase H,
Czurkó A,
Mamiya A,
Buzsáki G
(1999)
Oscillatory coupling of hippocampal pyramidal cells and interneurons in the behaving rat.
J Neurosci
19:274-287[Abstract/Free Full Text].
-
Fox SE,
Wolfson S,
Ranck Jr JB
(1986)
Hippocampal theta rhythm and the firing of neurons in walking and urethane anesthetized rats.
Exp Brain Res
62:495-508[Web of Science][Medline].
-
Freund TF,
Antal M
(1988)
GABA-containing neurons in the septum control inhibitory interneurons in the hippocampus.
Nature
336:170-173[Medline].
-
Freund TF,
Buzsáki G
(1996)
Interneurons of the hippocampus.
Hippocampus
6:347-470[Web of Science][Medline].
-
Frotscher M,
Leranth C
(1985)
Cholinergic inervation of the rat hippocampus as revealed by choline acetyltransferase immunocytochemistry: a combined light and electron microscopic study.
J Comp Neurol
239:237-246[Web of Science][Medline].
-
Gaykema RPA,
van der Kuil J,
Hersh LB,
Luiten PGM
(1991)
Patterns of direct projections from the hippocampus to the medial septum-diagonal band complex: anterograde tracing with Phaseoulus vulgaris leucoagglutinin combined with immunohistochemistry of choline acetyltransferase.
Neuroscience
43:349-369[Web of Science][Medline].
-
Gaztelu JM,
Buño W
(1982)
Septo-hippocampal relationships during EEG theta rhythm.
Electroencephalogr Clin Neurophysiol
54:375-387[Web of Science][Medline].
-
Green JD,
Arduini AA
(1954)
Hippocampal electrical activity in arousal.
J Neurophysiol
17:533-557[Free Full Text].
-
Griffith WH,
Matthews RT
(1986)
Electrophysiology of AChE-positive neurons in basal forebrain slices.
Neurosci Lett
71:169-174[Web of Science][Medline].
-
Gulyás AI,
Seress L,
Tóth K,
Acsády L,
Antal M,
Freund TF
(1991)
Septal GABAergic neurons innervate inhibitory interneurons in the hippocampus of the macaque monkey.
Neuroscience
41:381-390[Web of Science][Medline].
-
King C,
Recce M,
O'Keefe J
(1998)
The rhythmicity of cells of the medial septum/diagonal band of Broca in the awake freely moving rat: relationships with the behaviour and hippocampal theta.
Eur J Neurosci
10:464-477[Web of Science][Medline].
-
Kiss J,
Patel AJ
(1991)
Organisation and synaptic interconnections of parvalbumin and calbindin containing neurons in the rat septum.
In: Third IBRO World Congr Neurosci Abstr 323..
-
Köhler C,
Chan-Palay V,
Wu J-Y
(1984)
Septal neurons containing glutamic acid decarboxylase immunoreactivity project to the hippocampal region in the rat brain.
Anat Embryol
169:41-44[Medline].
-
Lee MG,
Chrobak JJ,
Sik A,
Wiley RG,
Buzsáki G
(1994)
Hippocampal theta activity following selective lesion of the septal cholinergic system.
Neuroscience
62:1033-1047[Web of Science][Medline].
-
Leranth C,
Frotscher M
(1989)
Organization of the septal region in the rat brain: cholinergic-GABAergic interconnections and the termination of hippocampo-septal fibers.
J Comp Neurol
289:304-314[Web of Science][Medline].
-
Leranth C,
Deller T,
Buzsáki G
(1992)
Intraseptal connections redefined: lack of a lateral septum to medial septum path.
Brain Res
583:1-11[Web of Science][Medline].
-
Lewis PR,
Shute CCD,
Silver A
(1967)
Confirmation from choline acetylase analyses of a massive cholinergic innervation to the rat hippocampus.
J Physiol (Lond)
191:215-224[Abstract/Free Full Text].
-
Magee JC,
Johnston D
(1997)
A synaptically controlled, associative signal for Hebbian plasticity in hippocampal neurons.
Science
275:209-213[Abstract/Free Full Text].
-
Markram H,
Lubke J,
Frotscher M,
Sakmann B
(1997)
Regulation of synaptic efficacy by coincidence of postsynaptic APs and EPSPs.
Science
275:213-215[Abstract/Free Full Text].
-
Matthews RT,
Lee WL
(1991)
A comparison of extracellular and intracellular recordings from the medial septum/diagonal band neurons in vitro.
Neuroscience
42:451-462[Web of Science][Medline].
-
McLennan H,
Miller JJ
(1974)
The hippocampal control of neuronal discharges in the septum of the rat.
J Physiol (Lond)
237:607-624[Abstract/Free Full Text].
-
McLennan H,
Miller JJ
(1976)
Frequency-related inhibitory mechanisms controlling rhythmical activity in the septal area.
J Physiol (Lond)
254:827-841[Abstract/Free Full Text].
-
Mizumori SJ,
McNaughton BL,
Barnes CA,
Fox KB
(1989)
Preserved spatial coding in hippocampal CA1 pyramidal cells during reversible suppression of CA3c output: evidence for pattern completion in hippocampus.
J Neurosci
9:3915-3928[Abstract].
-
Paxinos G,
Watson C
(1997)
In: The rat brain in stereotaxic coordinates. San Diego: Academic.
-
Petsche H,
Stumpf CH,
Gogolak G
(1962)
The significance of the rabbit's septum as a relay station between the midbrain and the hippocampus. I. The control of hippocampus arousal activity by the septum cells.
Electroencephalogr Clin Neurophysiol
14:202-211[Web of Science][Medline].
-
Raisman G
(1966)
The connexions of the septum.
Brain
89:317-348[Free Full Text].
-
Ranck Jr JB
(1973)
Studies on single neurons in dorsal hippocampal formation and septum in unrestrained rats. I. Behavioral correlates and firing repertoires.
Exp Neurol
41:461-531[Medline].
-
Serafin M,
Williams S,
Khateb A,
Fort P,
Mühlethaler M
(1996)
Rhythmic firing of medial septum non-cholinergic neurons.
Neuroscience
75:671-675[Web of Science][Medline].
-
Shute CCD,
Lewis PR
(1963)
Cholinesterase-containing systems of the brain of the rat.
Nature
199:1160-1164[Medline].
-
Shute CCD,
Lewis PR
(1966)
Electron microscopy of cholinergic terminals and acetylcholinesterase-containing neurones in the hippocampal formation of the rat.
Z Zellforsch Mikrosk Anat
69:334-343[Web of Science][Medline].
-
Skaggs WE,
McNaughton BL,
Wilson MA,
Barnes CA
(1996)
Theta phase precession in the hippocampal neuronal populations and the compression of temporal sequences.
Hippocampus
6:149-172[Web of Science][Medline].
-
Smythe JW,
Colom LV,
Bland BH
(1992)
The extrinsic modulation of hippocampal theta depends on the coactivation of cholinergic and GABA-ergic medial septal inputs.
Neurosci Biobehav Rev
16:289-308[Web of Science][Medline].
-
Staiger JF,
Nürnberger F
(1989)
Pattern of afferents to the lateral septum in the guinea pig.
Cell Tissue Res
257:471-490[Web of Science][Medline].
-
Staiger JF,
Nürnberger F
(1991)
The efferent connections of the lateral septum nucleus in the guinea pig: intrinsic connectivity of the septum and projections to other telencephalic areas.
Cell Tissue Res
264:415-426[Web of Science][Medline].
-
Stewart M,
Fox SE
(1989)
Firing relations of medial septal neurons to the hippocampal theta rhythm in urethane anesthetized rats.
Exp Brain Res
77:507-516[Web of Science][Medline].
-
Stewart M,
Fox SE
(1990)
Do septal neurons pace the hippocampal theta rhythm?
Trends Neurosci
13:163-168[Web of Science][Medline].
-
Stumpf Ch,
Petsche H,
Gogolak G
(1962)
The significance of the rabbit's septum as a relay station between the midbrain and the hippocampus. II. The differential influence of drugs upon both the septal cell firing pattern and the hippocampus theta activity.
Electroencephalogr Clin Neurophysiol
14:212-219[Web of Science][Medline].
-
Swanson LW,
Cowan WM
(1979)
The connections of the septal region in the rat.
J Comp Neurol
186:621-656[Web of Science][Medline].
-
Tóth K,
Freund TF
(1992)
Calbindin D28k-containing nonpyramidal cells in the rat hippocampus: their immunoreactivity for GABA and projection to the medial septum.
Neuroscience
49:793-805[Web of Science][Medline].
-
Tóth K,
Borhegyi Z,
Freund TF
(1993)
Postsynaptic targets of GABAergic hippocampal neurons in the medial septum-diagonal band of Broca complex.
J Neurosci
13:3712-3724[Abstract].
-
Tóth K,
Freund TF,
Miles R
(1997)
Disinhibition of rat hippocampal pyramidal cells by GABAergic afferents from the septum.
J Physiol (Lond)
500:463-474[Abstract/Free Full Text].
-
Tsubokawa H,
Ross WN
(1997)
Muscarinic modulation of spike backpropagation in the apical dendrites of hippocampal CA1 pyramidal neurons.
J Neurosci
17:5782-5791[Abstract/Free Full Text].
-
Van der Zee EA,
Luiten PGM
(1994)
Cholinergic and GABAergic neurons in the rat medial septum express muscarinic acetylcholine receptors.
Brain Res
652:263-272[Web of Science][Medline].
-
Vertes RP,
Kocsis B
(1997)
Brainstem-diencephalo-septohippocampal systems controlling the theta rhythm of the hippocampus.
Neuroscience
81:893-926[Web of Science][Medline].
-
Winson J
(1978)
Loss of hippocampal theta rhythm results in spatial memory deficit in the rat.
Science
210:160-163.
-
Ylinen A,
Bragin A,
Nadásdy Z,
Jando G,
Szabo I,
Sik A,
Buzsáki G
(1995)
Sharp wave-associated high frequency oscillation (200 Hz) in the intact hippocampus: network and intracellular mechanisms.
J Neurosci
15:30-46[Abstract].
Copyright © 1999 Society for Neuroscience 0270-6474/99/19146191-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
V. Varga, B. Hangya, K. Kranitz, A. Ludanyi, R. Zemankovics, I. Katona, R. Shigemoto, T. F. Freund, and Z. Borhegyi
The presence of pacemaker HCN channels identifies theta rhythmic GABAergic neurons in the medial septum
J. Physiol.,
August 15, 2008;
586(16):
3893 - 3915.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Manseau, R. Goutagny, M. Danik, and S. Williams
The Hippocamposeptal Pathway Generates Rhythmic Firing of GABAergic Neurons in the Medial Septum and Diagonal Bands: An Investigation Using a Complete Septohippocampal Preparation In Vitro
J. Neurosci.,
April 9, 2008;
28(15):
4096 - 4107.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Jinno, T. Klausberger, L. F. Marton, Y. Dalezios, J. D. B. Roberts, P. Fuentealba, E. A. Bushong, D. Henze, G. Buzsaki, and P. Somogyi
Neuronal Diversity in GABAergic Long-Range Projections from the Hippocampus
J. Neurosci.,
August 15, 2007;
27(33):
8790 - 8804.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. Calandreau, R. Jaffard, and A. Desmedt
Dissociated roles for the lateral and medial septum in elemental and contextual fear conditioning
Learn. Mem.,
June 6, 2007;
14(6):
422 - 429.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. E. Gipson and M. F. Yeckel
Coincident Glutamatergic and Cholinergic Inputs Transiently Depress Glutamate Release at Rat Schaffer Collateral Synapses
J Neurophysiol,
June 1, 2007;
97(6):
4108 - 4119.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Orban, T. Kiss, and P. Erdi
Intrinsic and Synaptic Mechanisms Determining the Timing of Neuron Population Activity During Hippocampal Theta Oscillation
J Neurophysiol,
December 1, 2006;
96(6):
2889 - 2904.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Kepecs, N. Uchida, and Z. F. Mainen
The Sniff as a Unit of Olfactory Processing
Chem Senses,
February 1, 2006;
31(2):
167 - 179.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. Borhegyi, V. Varga, N. Szilagyi, D. Fabo, and T. F. Freund
Phase Segregation of Medial Septal GABAergic Neurons during Hippocampal Theta Activity
J. Neurosci.,
September 29, 2004;
24(39):
8470 - 8479.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. I. Anderson and S. M. O'Mara
Analysis of Recordings of Single-Unit Firing and Population Activity in the Dorsal Subiculum of Unrestrained, Freely Moving Rats
J Neurophysiol,
August 1, 2003;
90(2):
655 - 665.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Hajos, W. E. Hoffmann, and R. J. Weaver
Regulation of Septo-Hippocampal Activity by 5-Hydroxytryptamine2C Receptors
J. Pharmacol. Exp. Ther.,
August 1, 2003;
306(2):
605 - 615.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. E. Mikkonen, T. Gronfors, J. J. Chrobak, and M. Penttonen
Hippocampus Retains the Periodicity of Gamma Stimulation In Vivo
J Neurophysiol,
November 1, 2002;
88(5):
2349 - 2354.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
X.-J. Wang
Pacemaker Neurons for the Theta Rhythm and Their Synchronization in the Septohippocampal Reciprocal Loop
J Neurophysiol,
February 1, 2002;
87(2):
889 - 900.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. D. Manns, A. Alonso, and B. E. Jones
Discharge Profiles of Juxtacellularly Labeled and Immunohistochemically Identified GABAergic Basal Forebrain Neurons Recorded in Association with the Electroencephalogram in Anesthetized Rats
J. Neurosci.,
December 15, 2000;
20(24):
9252 - 9263.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. A. White, M. I. Banks, R. A. Pearce, and N. J. Kopell
Networks of interneurons with fast and slow gamma -aminobutyric acid type A (GABAA) kinetics provide substrate for mixed gamma-theta rhythm
PNAS,
June 23, 2000;
(2000)
100124097.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
D. Ji and J. A. Dani
Inhibition and Disinhibition of Pyramidal Neurons by Activation of Nicotinic Receptors on Hippocampal Interneurons
J Neurophysiol,
May 1, 2000;
83(5):
2682 - 2690.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. A. White, M. I. Banks, R. A. Pearce, and N. J. Kopell
Networks of interneurons with fast and slow gamma -aminobutyric acid type A (GABAA) kinetics provide substrate for mixed gamma-theta rhythm
PNAS,
July 5, 2000;
97(14):
8128 - 8133.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
