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The Journal of Neuroscience, January 1, 2002, 22(1):324-337
Cellular Mechanisms of Infralimbic and Prelimbic Prefrontal
Cortical Inhibition and Dopaminergic Modulation of Basolateral Amygdala
Neurons In Vivo
J. Amiel
Rosenkranz1 and
Anthony A.
Grace1, 2
Departments of 1 Neuroscience and
2 Psychiatry, University of Pittsburgh, Pittsburgh,
Pennsylvania 15260
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ABSTRACT |
The basolateral amygdala (BLA) is believed to be involved in
schizophrenia, depression, and other disorders that display affective components. The neuronal activity of the BLA, and BLA-mediated affective behaviors, are driven by sensory stimuli transmitted in part
from sensory association cortical regions. These same behaviors may be
regulated by prefrontal cortical (PFC) inputs to the BLA. However, it
is unclear how two sets of glutamatergic inputs to the BLA can impose
opposing actions on BLA-mediated behaviors; specifically, it is unclear
how PFC inputs exert inhibitory actions over BLA projection neurons.
Dopamine (DA) receptor activation enhances BLA-mediated behaviors.
Although we have demonstrated that DA suppresses medial PFC
inputs to the BLA and enhances sensory cortical inputs, the precise
cellular mechanisms for its actions are unknown. In this study we use
in vivo intracellular recordings to determine the means
by which glutamatergic inputs from the PFC inhibit BLA projection
neurons, contrast that with glutamatergic inputs from the association
sensory cortex (Te3) that drive BLA projection neurons, and examine the
effects of DA receptor activation on neuronal excitability, spontaneous
postsynaptic potentials (PSPs), and PFC-evoked PSPs. We found that PFC
stimulation inhibits BLA projection neurons by three mechanisms:
chloride-mediated hyperpolarization, a persistent decrease in neuronal
input resistance, and shunting of PSPs; all effects are possibly
attributable to recruitment of inhibitory interneurons. DA
receptor activation enhanced neuronal input resistance by a
postsynaptic mechanism (via DA D2 receptors), suppressed spontaneously
occurring and PFC-evoked PSPs (via DA D1 receptors), and enhanced
Te3-evoked PSPs.
Key words:
dopamine; basolateral amygdala; prefrontal cortex; sensory association cortex; Te3; in vivo
intracellular
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INTRODUCTION |
Cortical inputs to the basolateral
amygdala (BLA) are believed to regulate amygdala-mediated behaviors.
Sensory cortical areas drive amygdala-mediated behaviors in response to
sensory stimuli laden with affective value (LeDoux et al., 1990 ;
Campeau and Davis, 1995; Uwano et al., 1995; Armony et al., 1997;
Poremba et al., 1998), whereas prefrontal cortical (PFC) areas suppress
some of these behaviors (Al Maskati and Zbrozyna, 1989; Zbrozyna and
Westwood, 1991; Jaskiw and Weinberger, 1992; Morgan and LeDoux, 1995;
Dias et al., 1996; Jinks and McGregor, 1997). Using extracellular
recording techniques, we have demonstrated previously (Rosenkranz and
Grace, 2001) that PFC inputs excite inhibitory interneurons of the
BLA (composed of the lateral nucleus, basal nucleus, and
accessory basal nucleus) (Alheid et al., 1995), and this may be a
mechanism by which the PFC regulates BLA output and thus suppresses
BLA-mediated behaviors. However, inputs from sensory association
cortical areas (Te3, entorhinal and perirhinal cortices) also activate
interneurons and produce inhibition (Lang and Pare, 1997, 1998; Szinyei
et al., 2000; Rosenkranz and Grace, 2001), but instead of suppression of BLA-mediated behaviors, these inputs appear to drive them. Inhibition may be used to completely suppress output of projection neurons, or it may be able to increase the fidelity of projection neuron firing in response to an input (Hata et al., 1988; Nelson et
al., 1994; Vidyasagar et al., 1996; Shevelev et al., 1998; Anderson et
al., 2001). On a cellular level, this may appear as cortically evoked
feedforward inhibition that excludes projection neuron firing, or as
excitation followed by inhibition, respectively (Freund and Buzsaki,
1996; Chung and Ferster, 1998; Anderson et al., 2000). Functionally,
the former completely suppresses BLA output in a time-locked manner,
whereas the latter sharpens, or tunes, the transmitted signal. To
understand the mechanism by which glutamatergic PFC and sensory
association cortical inputs implement distinct behavioral actions, the
effects of the inputs on BLA neuronal membrane potential and
excitability should be examined. In this paper, we have examined the
means by which PFC stimulation inhibits BLA neuronal firing while
sensory cortical stimulation drives it.
Dopamine (DA) receptor activation alters neuronal activity in a complex
manner via effects on afferents as well as seemingly opposing effects
on somatodendritic conductances (Cepeda et al., 1993; Geijo-Barrientos
and Pastore, 1995; Yang and Seamans, 1996; Flores-Hernandez et al.,
1997; Behr et al., 2000). However, from a functional standpoint, this
modulation of afferents and somatic excitability may in fact be
complementary. We have demonstrated previously that DA receptor
activation attenuates PFC inputs to the BLA while enhancing sensory
cortical inputs (Rosenkranz and Grace, 2001). Thus, the overall effect
of DA is the removal of PFC-induced suppression of neuronal output and
enhanced activity driven by sensory cortical inputs. Furthermore, DA
receptor activation increases the firing rate of local inhibitory
interneurons, inhibiting BLA projection neurons (Ben-Ari and Kelly,
1976; Spehlmann and Norcross, 1984; Rosenkranz and Grace, 1999) and
perhaps decreasing spurious responses of BLA projection neurons. Thus,
via seemingly opposing effects on inputs, BLA interneurons, and
projection neurons, DA may in fact aid in the coordination of an
affective response to a sensory stimulus. Although DA appears to exert
such actions on a behavioral level (Willick and Kokkinidis, 1995;
Borowski and Kokkinidis, 1996; Harmer et al., 1997; Lamont and
Kokkinidis, 1998; Guarraci et al., 1999; Nader and LeDoux, 1999; See et
al., 2001), the cellular mechanisms and receptor pharmacology that underlie this modulation are unclear. Here we have examined the effects
of DA receptor manipulations on neuronal excitability and spontaneously
occurring as well as cortically evoked postsynaptic potentials (PSPs),
using in vivo intracellular recordings to further elucidate
the sites at which DA exerts its actions. A portion of these results
have been published previously in abstract form (Rosenkranz and Grace,
2000).
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MATERIALS AND METHODS |
Materials. Eticlopride, apomorphine, quinpirole,
SKF-81297, and SKF-38393 were purchased from Sigma (St. Louis,
MO) and dissolved in 0.9% saline to a concentration of 0.5, 1.0, or
3.0 mg/ml. Haloperidol was a generous gift from McNeil Laboratories
(Spring House, PA); it was dissolved in dilute lactic acid and then
diluted further with 0.9% saline to a concentration of 0.5 mg/ml.
Animal preparation. All procedures were performed in
accordance with the National Institutes of Health Guide for the
Care and Use of Laboratory Animals and were approved by the
University of Pittsburgh Institutional Animal Care and Use Committee.
Male Sprague Dawley rats (250-410 gm weight) were housed in pairs in a
temperature-controlled environment with a 12 hr on/off light/dark schedule. Food and water were available ad libitum. Rats
were anesthetized with an initial injection of 8% chloral hydrate (400 mg/kg, i.p.). Supplemental anesthesia (8% chloral hydrate) was delivered via a lateral tail-vein catheter as necessary to maintain suppression of hindlimb withdrawal reflex. Rats were placed on a
temperature-controlled heating pad (Heater VL-20F; Fintronics, Orange,
CT) and their temperature was monitored (Precision Thermometer 4600;
Yellow Springs Instruments, Yellow Springs, CO) and maintained at
~37°C. The rats were placed in a stereotaxic device (Kopf
Instruments, Tujunga, CA), and incisions were made in the scalp to
expose the skull. Burr holes were drilled and the dura was removed
overlying the BLA and medial PFC (mPFC) or Te3. Coordinates were
determined using a stereotaxic atlas (Paxinos and Watson, 1997), as
follows: BLA,  5.0 lateral, 3.3 caudal from bregma; mPFC
(prelimbic/infralimbic cortex), 0.7 lateral, +2.2 to +3.0 rostral
from bregma; Te3, 6.0 lateral, +2.2 rostral from the interaural line.
Concentric bipolar stimulating electrodes (Rhodes Medical Instruments,
Inc., obtained from Kopf Instruments) were lowered into the mPFC or Te3
(at the coordinates listed above) to a depth of 5.0 mm. Experiments started no earlier than 45 min after stimulating electrode placement. Neurons were recorded from the lateral and basal nuclei of the amygdala.
Intracellular recordings. Electrodes were constructed using
borosilicate glass tubing (1.5 mm outer diameter, 0.84 mm inner diameter; World Precision Instruments, Sarasota, FL) pulled with a Flaming-Brown micropipette puller (model P-80/PC; Sutter
Instruments, Novato, CA). Electrodes were filled with 2% biocytin in 3 M potassium acetate (Sigma). Impedances were
measured in situ and ranged from 45 to 100 M . Electrodes
were slowly lowered to the BLA via a hydraulic micromanipulator (model
640, Kopf Instruments). A stimulator (Grass S88; Grass Instruments,
Quincy, MA) in series with an intracellular recording amplifier
(IR-283; Neuro Data Instruments, New York, NY) and a stimulus isolation
unit (PSIU6; Grass Instruments) was used to deliver pulses of constant
DC (150 msec, 0.07 nA). Electric potentials were monitored
visually with an oscilloscope (Hitachi V134; Hitachi, Tokyo, Japan) and
a multimeter (model 179A; Keithley, Cleveland, OH) and audially with a
Grass AM5 audio monitor (Grass Instruments). Data were fed to a PC,
monitored using custom-designed software (Neuroscope), and
stored on a hard disk for analysis offline. Data were also digitized
(Neuro-corder DR-484; Neuro Data Instruments) and saved on video tapes
using a videocassette recorder (Panasonic AG-1280; Panasonic, Secaucus,
NJ). At the completion of experiments, neurons were
hyperpolarized with negative current to below spike threshold, and
positive DC pulses (0.1-1.0 nA, 250 msec, 2 Hz) were used to eject
biocytin from the electrode. Rats were perfused transcardially with
0.85% cold saline followed by 4% paraformaldehyde in 0.1 M phosphate buffer. Brains were removed, stored
in the perfusion fixative, and then cryoprotected in a 25% sucrose 0.1 M phosphate buffer solution. Brains were sliced
on a freezing microtome into 60- to 80-µm-thick sections and labeled
for biocytin using the Vectastain Elite avidin-biotin complex
peroxidase kit (Vector Laboratories Inc., Burlingame, CA). Sections
were counterstained with a custom mixture of cresyl violet and neutral
red stains, and stimulating electrode and recording electrode
placements were identified as described previously (Rosenkranz and
Grace, 2001).
Data collection and analysis. After collection of several
minutes of baseline data, DC pulses were injected into the
neurons (±0.02-1.2 nA; 250-350 msec; 0.2-0.4 Hz). Hyperpolarizing
pulses were used to determine the input resistance of the neurons. In some experiments the mPFC or Te3 was stimulated (0.7-1.2 mA; 0.3 msec;
Grass S88 stimulator; Grass PSIU6 stimulus isolation unit) at the last
100 msec of the DC pulse to examine the effects of membrane potential
on evoked PSPs. For data analysis, a stimulation intensity of 0.7 mA
was used for comparisons because it was consistently below
action-potential threshold at resting membrane potentials and it evoked
responses that were ~50-75% of maximum PSP amplitude. Drugs were
administered intravenously, and the above procedure was repeated.
Mean resting membrane potential was determined from 30 sec sampling
periods, and action potentials were eliminated from this analysis.
Neuronal input resistance was determined from the voltage deflections
resulting from injection of DC pulses. Only hyperpolarizing DC pulses
were used for this analysis, and only the linear portion of the plot
was included to determine input resistance. In addition, the input
resistance was determined only from traces that displayed no
co-occurring membrane fluctuations/PSPs. The peak amplitude of
stimulus-evoked PSPs was examined as a function of membrane potential.
The peak amplitude was defined as the largest difference from
prestimulus baseline in the absence of coincident spontaneous PSPs. The
peak latency was measured from the time of stimulation. Action-potential threshold was defined as the onset of the rapid transition in membrane potential at the initiation of the spike. The
amplitude of the action potential was the voltage difference between
the threshold and the action-potential peak. The duration of action
potentials was measured as the time between action-potential initiation
at spike threshold and the return to baseline preceding the
afterhyperpolarization, if present. The membrane potential calculated
during intracellular recording was adjusted based on the difference
obtained after withdrawal of the electrode from the neuron after the
recording. In an attempt to quantify spontaneously occurring PSPs, the
SD of the membrane potential was quantified [similar to Pare et al.
(1998)]. The SD of the mean membrane potential was calculated from 30 sec epochs. Action potentials were removed from this analysis if they
were observed in the 30 sec epoch by setting a cutoff at
action-potential threshold. To examine the effect of membrane potential
on SD, 15 sec epochs were used while the neuron was directed to
different membrane potentials with constant intracellular current
injection. The normalized SD (SD at given membrane potential/largest SD
measured for that neuron) was plotted against membrane potential and
fit with a linear function. The reversal potential was extrapolated to
the x-intercept of this plot. Using similar methods, the
reversal potentials of components of evoked and spontaneous PSPs were
examined. Neurons were excluded from analysis if their action
potentials did not overshoot a 0 mV membrane potential or if they were
less polarized than 55 mV. Paired t tests were used to
examine the effects of drugs on resting membrane potential, SD,
action-potential parameters, firing rate, and PSP amplitude. For all
other analyses, t tests on grouped data or Pearson
correlations were used. If data did not fit a normal distribution, a
Mann-Whitney U test was used. For post hoc
comparisons, Bonferroni corrections of p values were performed.
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RESULTS |
Basic electrophysiological properties of BLA neurons
All recordings were obtained from neurons of the lateral or basal
nuclei of the BLA. No differences in the physiological properties were
observed, except as noted. Projection neurons of the BLA could be
distinguished from interneurons based on morphology, longer
action-potential duration, and the ability to be antidromically activated (Washburn and Moises, 1992; Rainnie et al., 1993; Sugita et
al., 1993; Gaudreau and Pare, 1996). Using a mixture of these criteria,
a total of 139 neurons were categorized as projection neurons and were
located in the BLA. When recovered, the projection neurons had
morphologies consistent with previously described BLA projection
neurons (McDonald, 1985; Washburn and Moises, 1992; Rainnie et al.,
1993; Sugita et al., 1993), as determined by biocytin labeling
(n = 9). They were typically pyramidal-like or oblong neurons, most of which displayed a primary dendrite (Fig.
1). When secondary dendrites were filled,
dendritic spines were observed. Some of the recorded neurons could be
antidromically activated from mPFC stimulation (in that the action
potentials exhibited constant latency and arose directly from the
resting membrane potential with no evidence of an underlying EPSP, and
followed 300 Hz stimulation when tested) (Fig. 1). In addition, these
neurons displayed electrophysiological characteristics similar to
projection neurons described previously (Washburn and Moises, 1992;
Rainnie et al., 1993; Sugita et al., 1993). This consisted of action
potentials with a duration of 2.1 ± 0.06 msec (mean ± SEM),
69.0 ± 0.8 mV amplitude, a slow firing rate of 0.09 ± 0.04 Hz (range, 0-0.62 Hz), and a hyperpolarized mean membrane potential
(78.4 ± 0.9 mV). These projection neurons also had a mean
action-potential threshold of 55.8 ± mV and input resistances
of 38.9 ± 1.4 M (ranging from 15.9 to 79.6 M) (Fig. 1).
Most projection neurons displayed clear spike accommodation in response
to suprathreshold depolarizing current injection (97 of 114 neurons tested), and delayed rectification of the membrane
potential in response to hyperpolarizing current pulses was observed in
a subset of neurons.
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Figure 1.
BLA projection neurons. Projection
neurons of the BLA can be identified by antidromic activation
(A), demonstrated by constant response latency
(top, arrow 1) in the absence of
a PSP (top, arrow 2), and by the
ability to follow high-frequency stimulation (A,
bottom). The excitability of these neurons can be
estimated by membrane deflections in response to intracellular current
injection (B, projection neuron; C,
interneuron), yielding a measurement of input resistance
(D, black circles, projection neurons, 32 M; white circles, interneurons, 46 M). Also note
that projection neurons display spike accommodation, whereas
interneurons of the BLA do not (B, C),
and interneurons exhibit shorter duration action potentials
(E, bottom trace) when compared with
projection neurons (E, top trace).
Neurons identified post hoc had morphologies consistent
with projection neurons (F); Scale bar,
20 µm.
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The level of spontaneous membrane fluctuations varied dramatically
between BLA neurons; some displayed little fluctuation, whereas others
displayed activity reminiscent of the bistable membrane states observed
in cortical and striatal neurons (Steriade et al., 1993; Wilson, 1993;
O'Donnell and Grace, 1995; Stern et al., 1997), with transitions of
close to 10 mV. However, unlike the bistable neurons of the striatum,
BLA neurons were not truly bistable. Thus, although membrane
depolarizations were observed, the membrane potential of these plateaus
varied in an almost continuous nature, stable plateaus were rare, and
the duration was highly variable (Fig.
2). The frequency and magnitude of
membrane potential fluctuations in the BLA neurons can be roughly
estimated with the SD of the membrane potential (Pare et al., 1998).
The mean SD was 2.69 ± 0.13 mV, and ranged from 0.58 to 7.10. These fluctuations may be attributable to barrages of PSPs, intrinsic
subthreshold oscillations, or a combination of the two. There appeared
to be little or no effect of membrane voltage (120 to 70 mV) on the frequency of these oscillations, whereas the amplitude was sensitive to
the membrane potential (Fig. 2), indicating that the occurrence of
these fluctuations is not attributable to intrinsic oscillations of the
membrane potential (Pare et al., 1995) but is probably synaptic in
nature. Under the assumption that the SD approaches zero near the
reversal potential of the membrane fluctuations represented by the SD,
additional evidence that these membrane fluctuations are attributable
to synaptic potentials is derived from extrapolation of the reversal
potential of the normalized SD as a function of membrane potential
(Fig. 2) (n = 14 neurons). The reversal potential was
extrapolated to 23 mV (using the linear portion of the plot of SD as
a function of membrane potential and non-normalized data), consistent
with PSPs. To further validate this possibility, the amplitudes of
large spontaneous PSPs were measured over varying membrane potentials
and analyzed as a function of membrane potential. The reversal
potential was extrapolated to 25 mV. In addition, the difference
between the mean membrane potential and the resting membrane potential
was plotted as a function of the resting membrane potential (the
reversal potential was extrapolated to 36 mV) (Fig.
2F, inset). Thus, the magnitude of the
spontaneous fluctuations decreased with depolarizing membrane potentials, consistent with a reduction of driving force for
spontaneous PSPs. However, it should be noted that in two neurons
depolarization above approximately 60 mV resulted in fast (~10 Hz)
oscillations similar to oscillations reported previously (Pape et al.,
1998). Only a weak, insignificant correlation between the SD of the
membrane potential and the input resistance was seen here (Pearson
r2 = 0.03; p > 0.05) (Fig. 2), indicating that our measurement of input resistance was
not dependent on the level of synaptic activity.
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Figure 2.
Spontaneous activity of BLA
projection neurons. BLA neurons display spontaneous membrane
deflections (A) that can be estimated by the SD
of the membrane potential (SD is 2.8 mV in this case); this SD
can be demonstrated by a histogram of the time spent at a given
membrane potential (B). The fluctuations are not
systematically associated with input resistance
(C), but the amplitude is dependent on the
membrane potential (D) (also note the reversal of
many PSPs near 65 mV, as demonstrated by hyperpolarizing PSPs), as
indicated by a plot of normalized SD as a function of membrane
potential (E) (group data, n = 14). This indicates that the fluctuations are likely to reflect
spontaneous inputs. The inset in E plots
the difference between the mean membrane potential and the resting
membrane potential in several neurons (n = 14) as a
function of membrane potential. Voltages listed beside intracellular
traces are the resting membrane potentials.
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Fewer neurons that fit the classification of interneurons were
successfully recorded (n = 6). These neurons displayed
shorter duration action potentials (1.1 ± 0.1 msec), less
polarized resting membrane potentials (66.0 ± 3.6), a spike
threshold closer to the resting membrane potential (61 ± 2 mV),
nonaccommodating spike trains in response to depolarizing current
injection, and a tendency toward larger input resistance values
(46 ± 12 M). The spontaneous membrane fluctuations at resting
membrane potentials could not be accurately measured because of the
significantly higher frequency of action-potential discharge (2.2 ± 0.9 Hz, p < 0.05 t test
t = 8.1) that was often followed by long-duration hyperpolarizations that may be afterhyperpolarizing potentials and/or
feedback-collateral inhibition.
Properties of Te3- and PFC-evoked PSPs
As may be expected based on behavioral evidence (see the
introductory remarks) and as extrapolated from our previous
extracellular recording studies (Rosenkranz and Grace, 2001), there
were dramatic differences between the PFC- and Te3-evoked actions.
Stimulation of the mPFC resulted in PSPs with an amplitude that was
dependent on stimulus intensity (Fig. 3).
At resting membrane potentials, the response was a depolarizing
potential (6.5 ± 0.8 mV; n = 39; peak latency,
29.4 ± 1.5 msec) that was sometimes followed by a longer duration
hyperpolarization. However, it became evident that the initial
depolarizing potential was not excitatory in nature when the membrane
potential was directed to less polarized potentials using intracellular
current injection (Fig. 3). Thus, at depolarized membrane potentials
(typically less than 60 mV), PFC stimulation resulted in a
hyperpolarization of the membrane potential. The reversal potential of
the first component was 66.6 mV (n = 39), consistent
with a GABA-activated chloride conductance (Fig. 3). The second
component was typically of a small magnitude and could not be measured
accurately; however, it appeared to reverse between 90 and 100 mV,
consistent with a potassium conductance. In some instances, a
depolarizing potential (8.3 ± 1.6 mV at resting membrane
potentials; peak latency, 19.9 ± 1.5 msec; 0.7 mA stimulation) could be seen preceding (n = 3 of 39 neurons;
all 3 neurons in the lateral nucleus) or within (n = 6 of 39 neurons) the initial, presumably GABAergic,
hyperpolarizing potential. This small depolarizing potential did not
reverse over the membrane potentials tested (140 to 50 mV; reversal
potential extrapolated to 34.2 mV) and may reflect a glutamatergic
component that is entirely overwhelmed by concurrent GABAergic effects.
PFC stimulation evoked a monosynaptic spike in 3 of 39 neurons only,
and this spike occurred at the peak of this latter depolarizing
component. Attempts to examine the EPSP component at the
reversal potential of the IPSP were not successful because of the small
amplitude of the EPSP at this membrane potential. Thus, mPFC
stimulation typically resulted in an IPSP that precluded spike firing
and usually occluded any EPSP if present. This mPFC-evoked inhibition
was present in the vast majority of neurons encountered, regardless of
recording location within the BLA.
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Figure 3.
Response to mPFC stimulation.
A, The PSP amplitudes evoked by mPFC stimulation are
stimulus intensity-dependent. (Voltage traces of responses to 0.1, 0.4, and 0.7 mA of stimulation are displayed.) Intracellular voltage traces
indicate that mPFC stimulation evokes PSPs that reverse close to the
chloride reversal potential (B, arrow
2) and sometimes PSPs that are extrapolated to reverse
near 30 mV (B, arrow 1).
C, The reversal potential of the primary PSP evoked in
the neuron in B, demonstrated by the intersection of
baseline membrane potential (filled circles) and
PSP amplitude (open circles) in a plot of PSP amplitude
as a function of membrane potential, is 67 mV. The grouped data
(n = 39) plot of the PSP amplitude by membrane
potential (D) for the EPSPs (white
circles) and the IPSPs (black circles)
demonstrates that the IPSPs reverse near the chloride reversal
potential (dashed line), whereas the EPSPs are
extrapolated to reverse near 20 mV (solid
line). In contrast, mPFC-evoked responses in striatal
neurons do not reverse near the chloride reversal potential
(E). Upward arrows indicate mPFC
stimulation.
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The mPFC-evoked IPSP is probably disynaptic, and not caused by
stimulation of an as yet unknown GABAergic projection, because PSPs
evoked from the same stimulation sites, recorded from striatal neurons,
do not reverse between 50 and 130 mV (Fig. 3). Therefore, this
IPSP is probably the result of mPFC excitation of BLA inhibitory interneurons. This is supported by mPFC-evoked depolarizations and
bursts of action potentials at resting membrane potentials in BLA
neurons tentatively identified as interneurons (n = 3 of 3 neurons) (Fig. 4) based on the
criteria described above. Additional evidence that the mPFC-evoked IPSP
is not monosynaptic is derived from the decrease in onset latency with
increased stimulation intensity and from the additional components of
the response that are evoked in a nonlinear manner with increasing
stimulation intensity (Fig. 3).
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Figure 4.
Inhibition evoked by mPFC stimulation. mPFC
stimulation evokes a depolarizing potential and spikes in interneurons
(A, top) as well as hyperpolarization in
projection neurons (A, bottom). In
addition to the hyperpolarization, mPFC stimulation produces a
prolonged decrease in neuronal input resistance
(B) and shunts spontaneous PSPs
(C), as reflected by the lack of spontaneous PSPs
after mPFC stimulation. Upward arrows indicate mPFC
stimulation. *Significant difference from baseline; p < 0.05; paired t test.
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Injections of brief hyperpolarizing current pulses (0.3-0.7 nA,
70-200 msec; n = 5) after mPFC stimulation
demonstrated a decrease in input resistance, lasting ~100 msec from
the onset of the mPFC-evoked PSP (Fig. 4). The input resistance
remained significantly decreased for 120 msec compared with prestimulus input resistance (paired t tests, p < 0.05 with Bonferroni correction; df = 4) and returned to near baseline
input resistance values by 300 msec, indicating that mPFC inputs
inhibit BLA projection neurons by the chloride-mediated
hyperpolarization detailed above as well as by a persistent attenuation
of neuronal somatic excitability. It was also noted that mPFC
stimulation often resulted in a period of reduced spontaneous PSPs
(Fig. 4), perhaps indicative of GABAergic shunting of dendritic events.
Stimulation of Te3 also evoked PSPs with an amplitude that was
dependent on stimulation intensity (Fig.
5). Most Te3-evoked responses (17 of 18 responses) were recorded from neurons of the lateral nucleus. Neurons
outside of the lateral nucleus did not display robust monosynaptic
responses to Te3 stimulation. Similar to mPFC stimulation, a
depolarizing potential was evoked at resting membrane potentials.
However, as became evident with manipulations of the membrane
potential, there was an initial component that did not reverse at the
chloride reversal potential (15.2 ± 1.8 mV; n = 18; reversal potential extrapolated to 16.6 mV; peak latency,
16.5 ± 0.8 msec) and often resulted in action potentials at more
depolarized membrane potentials, usually (11 of 18 neurons) followed by
a component that reversed at 64.6 mV (n = 18;
8.2 ± 1.9 mV at resting membrane potentials; peak latency,
29.4 ± 1.6 msec). Thus, Te3 stimulation typically resulted in an
EPSP that was truncated by an IPSP. Although truncated by the IPSP, the
EPSP was always of sufficient magnitude to evoke action-potential discharge.
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Figure 5.
Excitatory response to Te3 stimulation.
A, Te3 stimulation evokes an intensity-dependent
PSP. (Voltage traces of responses to 0.1, 0.4, and 0.7 mA of
stimulation are displayed.) This PSP is composed of a component that
depolarizes at all membrane potentials tested (B,
arrow 1) and a component that appears to reverse
near the chloride reversal potential (B, arrow
2). In this neuron, the second component reverses at
65 mV, as determined by the intersection of the membrane potential
(C, dashed line, time point 2 in
B) and the IPSP amplitude in response to hyperpolarizing
pulses of current (C, solid line,
time point 1 in B). D, In grouped data
(n = 18 neurons), it can be demonstrated that the
IPSPs evoked by Te3 stimulation (black circles) reverse
near 65 mV (dashed line), whereas the evoked EPSPs
(white circles) reverse near 20 mV (solid
line) in a plot of PSP amplitude as a function of membrane
potential. Upward arrows indicate Te3 stimulation in all
traces.
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DAergic modulation of neuronal properties
Administration of the nonselective DA agonist apomorphine
(1.0 ± 0.15 mg/kg, i.v.; n = 8) consistently
increased input resistance (mean of 29%; 7 of 7 neurons; before
apomorphine, 40.7 ± 2.8 M; after apomorphine, 52.0 ± 5.4 M; p < 0.05; paired t test
t = 2.88; df = 6) (Fig.
6) and decreased the amplitude of
spontaneous membrane fluctuations (mean of 31%; 6 of 7 neurons; SD before apomorphine, 2.87 ± 0.17 mV; SD after
apomorphine, 1.99 ± 0.14 mV; p < 0.05; paired
t test; t = 4.80; df = 6) (Fig.
7). No significant or consistent changes
were seen in action-potential threshold, action-potential duration or
amplitude, resting membrane potential, or firing rate (Table
1). There was only a weak,
nonsignificant, correlation between the change in input resistance and
the change in SD after apomorphine administration (Pearson
r2 = 0.27).
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Figure 6.
DA receptor activation enhances
neuronal excitability. Apomorphine (1.2 mg/kg, i.v.) increases measured
voltage deflections in response to pulses of current injection
(A, left, before apomorphine) resulting
in enhanced input resistance and depolarization-evoked spike discharge
(A, right, after apomorphine). This was
reflected as an increase in input resistance (B)
(before apomorphine, solid circles,
Rin = 38 M; after apomorphine,
open circles, Rin = 47 M).
C, In all neurons tested, apomorphine administration
increased neuronal input resistance; *p < 0.05.
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Figure 7.
DAergic effects on spontaneous PSPs. DA
receptor activation (apomorphine, 1.2 mg/kg, i.v.) suppresses
spontaneous PSPs (A, before apomorphine, 3.1 mV, after
apomorphine, 1.7 mV, measured as SD of membrane potential), whereas DA
receptor blockade (haloperidol, 0.8 mg/kg, i.v.) enhances spontaneous
PSPs (B, before haloperidol, 1.6 mV, after haloperidol,
2.3 mV). C, Apomorphine consistently reduced spontaneous
PSPs (six of seven neurons), whereas haloperidol consistently enhanced
spontaneous PSPs (six of seven neurons); *p < 0.05.
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To determine whether tonic DA levels exert actions and may occlude the
actions of apomorphine, the DA antagonist haloperidol was administered.
Haloperidol administration (0.63 ± 0.06 mg/kg, i.v.) consistently
increased the amplitude of membrane fluctuations (47%; 6 of 7 neurons;
before haloperidol, 1.64 ± 0.34 mV; after haloperidol, 2.41 ± 0.39 mV; p < 0.05; paired t test;
t = 2.57; df = 6) (Fig. 7) and increased the
neuronal firing rate (5 of 7 neurons; before haloperidol, 0.10 ± 0.07 Hz; after haloperidol, 0.19 ± 0.08 Hz; p < 0.05; paired t test; t = 2.55; df = 6). By chance, the neurons recorded while administration of haloperidol occurred displayed a lower level of membrane fluctuations compared with
other groups, as measured by their SD. However, it is unlikely that the
opposite effects of apomorphine and haloperidol administration on SD
were entirely attributable to this difference in baseline SD, because
even neurons with a small SD (<0.9 mV) displayed a decreased SD in
response to apomorphine administration, whereas neurons with a higher
baseline SD (>3.3 mV) displayed an increase after haloperidol
administration. Changes in action-potential parameters, input
resistance, and membrane potential were not consistent or significant
(Table 1). These data indicate that tonic levels of DA may suppress
spontaneous membrane fluctuations, but do not necessarily exert tonic
actions on membrane excitability or action-potential parameters.
In an attempt to determine which DA receptors are responsible for
alterations in neuronal excitability and spontaneous membrane fluctuations, specific DA receptor agonists were used. Administration of the DA D2 agonist quinpirole (0.79 ± 0.09 mg/kg, i.v.)
increased neuronal input resistance (39%; 6 of 7 neurons; before
quinpirole, 35.3 ± 5.2 M; after quinpirole, 49.1 ± 5.6 M; p < 0.05; paired t test;
t = 2.52; df = 6) (Fig.
8) but had no significant actions on any
other measurement (Table 1). In contrast, administration of the DA D1
agonists SKF-38393 (0.49 ± 0.15 mg/kg, i.v.; n = 3) or SKF-81296 (6.1 ± 0.28 mg/kg, i.v.; n = 4)
had no effect on input resistance (Fig.
9) but consistently decreased the
amplitude of spontaneous membrane fluctuations (23%; 7 of 7 neurons;
before SKF, 3.14 ± 0.80 mV; after SKF, 2.43 ± 0.81 mV;
p < 0.05; paired t test; t = 3.41; df = 6) (Fig. 10); no
other consistent or significant measured actions were observed (Table
1). Thus, different DA receptor subtypes exert actions on somatic input
resistance and spontaneous PSPs.
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Figure 8.
DA D2 receptor activation enhances
neuronal excitability. Administration of the DA D2 agonist quinpirole
(0.6 mg/kg, i.v.) enhanced membrane deflections in response to
intracellular current injection (A, before quinpirole,
58 M; B, after quinpirole, 71 M). This is
demonstrated by overlaying voltage traces in response to 1 nA of
current injection before and after quinpirole (C)
showing an enhanced response after quinpirole, as well as by a plot of
input resistance (D; dashed line
after quinpirole). E, Quinpirole consistently increased
neuronal input resistance (six of seven neurons);
*p < 0.05.
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Figure 9.
DA D1 receptor activation does not
enhance neuronal excitability. Administration of the DA D1 agonist
SKF-81297 (6 mg/kg, i.v.) did not alter neuronal responses to current
injection (A, before SKF-81297, 28 M;
B, after SKF-81297, 26 M). Responses to 1.0 nA of
current injection (C) as well as input resistance
plots (D) overlay closely. E,
Administration of the DA D1 agonists SKF-81297 or SKF-38393 did not
have a significant effect on neuronal input resistance.
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Figure 10.
DA D1 receptor activation but not D2 stimulation
suppresses spontaneous PSPs. Administration of the DA D1 agonist
SKF-81297 (6 mg/kg, i.v.) suppresses spontaneous PSPs
(A), as demonstrated by decreased fluctuation of
the membrane potential in a histogram of percentage of time spent at a
given membrane potential (B, SD of membrane potential
before SKF-81297, 1.8 mV; SD of membrane potential after SKF-81297, 0.6 mV). Administration of the DA D2 agonist quinpirole (1.2 mg/kg, i.v.)
did not suppress spontaneous PSPs (C), nor did it
alter the distribution of membrane potential over time
(D, SD before quinpirole, 3.4 mV; SD after quinpirole,
3.3 mV). E, Whereas administration of the DA D1 agonists
attenuated spontaneous PSPs (seven of seven neurons), the DA D2 agonist
quinpirole had no significant effect; *p < 0.05.
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DAergic modulation of PFC inputs
We have demonstrated previously that apomorphine suppresses
mPFC-evoked inputs to the BLA (Rosenkranz and Grace, 2001). To determine whether this suppression is mediated by DA D1 or DA D2
receptors, specific agonists were used. To minimize the effects of
somatic membrane potential on the evoked PSP, all comparisons were
performed between PSPs measured at the same membrane potential.
The suppressive action of apomorphine on mPFC inputs appears to be
mediated by DA D1 receptors, because administration of the DA D1
agonists SKF-38393 (0.5 ± 0.01 mg/kg, i.v.; n = 3) or SKF-81297 (6.3 ± 0.7 mg/kg, i.v.; n = 3)
produced a powerful attenuation of the mPFC-evoked PSP (6 of 6 neurons;
mean of 70%; before SKF, 6.3 ± 1.5 mV; after SKF,
1.9 ± 0.1 mV; p < 0.05; paired t
test; t = 2.8; df = 5) (Fig.
11). Administration of quinpirole
(0.8 ± 0.2 mg/kg, i.v.; n = 4) enhanced the
amplitude of mPFC-evoked PSPs (Fig. 11), perhaps because of increased
somatic excitability, as demonstrated above (4 of 4 neurons; before
quinpirole, 13.3 ± 3.1 mV; after quinpirole, 15.4 ± 3.3 mV;
p < 0.05; paired t test; t = 4.3; df = 3). To determine whether a portion of the response
to quinpirole may have been obscured because of pre-existing tonic
activation of DA D2 receptors, the specific DA D2 antagonist eticlopride was administered (0.7 ± 0.01 mg/kg, i.v.;
n = 5). At resting membrane potentials, eticlopride did
not have a significant effect on the mPFC-evoked PSP, although there
was a trend toward increased peak amplitude (before eticlopride,
5.4 ± 2.1 mV; after eticlopride, 8.6 ± 2.4 mV;
p > 0.05; paired t test; t = 1.5).
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Figure 11.
DA D1 receptor activation but not D2
stimulation suppresses mPFC-evoked PSPs. Administration of the DA D1
agonist SKF-81297 (6 mg/kg, i.v.) suppressed mPFC-evoked PSPs
(A, before SKF-81297, 11 mV; after SKF-81297, 0 mV).
Administration of the DA D2 agonist quinpirole (0.6 mg/kg, i.v.)
slightly enhanced mPFC-evoked responses (B, before
quinpirole, 12 mV; after quinpirole, 14 mV). C, The DA
D1 agonists consistently suppressed mPFC-evoked responses (six of six
neurons), whereas the DA D2 agonist consistently enhanced mPFC-evoked
responses (four of four neurons); *p < 0.05.
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To demonstrate that other, sensory-related inputs are not suppressed,
but in fact enhanced, by DA receptor activation, the effects of
apomorphine on Te3 inputs were examined. Apomorphine administration
(1.2 ± 0.1 mg/kg, i.v.; n = 4) enhanced
Te3-evoked EPSPs by 25% (4 of 4 neurons; before apomorphine, 10.7 ± 3.5 mV; after apomorphine, 13.3 ± 4.2 mV; paired t
test; p < 0.05; df = 3).
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DISCUSSION |
This study illustrates potential mechanisms by which glutamatergic
inputs from the mPFC are able to suppress BLA output, and the means by
which DA receptor activation suppresses the influence of mPFC inputs
while enhancing other inputs. On the whole, the data support the
hypothesis that mPFC inputs recruit BLA inhibitory interneurons to
suppress output, and that DA receptor activation removes mPFC-evoked
inhibition and enhances association sensory cortical inputs via
postsynaptic increases in neuronal excitability. Furthermore, these
data provide a mechanism by which mPFC inputs and DA receptor
activation exert such actions.
Inhibition of BLA projection neurons by mPFC inputs
It has been demonstrated previously that the PFC exerts a role in
behavior that goes beyond sensory processing, such as temporal organization and selection of behavior (Watanabe, 1986; Goldman-Rakic, 1995; Sawaguchi and Yamane, 1999; Miller and Cohen, 2001). The data
presented here demonstrate a means by which the PFC glutamatergic inputs may exert a functionally distinct action in the BLA, when compared with other glutamatergic inputs related to sensory processing. Thus, the mPFC inputs recruit inhibitory interneurons that result in a
threefold inhibition: chloride-mediated hyperpolarization or clamping
of the membrane potential to the chloride reversal potential,
persistent decreases in input resistance, and related shunting of
spontaneously occurring events. The contention that the mPFC-evoked
inhibition is mediated by BLA interneurons is consistent with what is
known about this system. Thus, there are few extrinsic sources of
GABAergic inputs to the BLA. Although one such source may be from the
ventral tegmental area (VTA) (Swanson, 1982), which receives excitatory
inputs from the mPFC (Tong et al., 1996, 1998; Carr and Sesack, 2000),
this disynaptic projection to the midbrain and back to the BLA would
probably take too long to account for the short-latency inhibition
observed here. In addition, the BLA has a large number of highly
collateralizing inhibitory interneurons (McDonald, 1982, 1985; McDonald
and Betette, 2001) that respond potently to mPFC stimulation
(Rosenkranz and Grace, 2001), and these intrinsic GABAergic inputs
would presumably overwhelm a much more sparse GABAergic input from the
VTA. Furthermore, we observed a close temporal relationship between the
latencies of the mPFC-evoked excitation of BLA interneurons and
inhibition of BLA projection neurons.
In contrast to mPFC inputs, Te3 inputs, as well as other
sensory-related inputs such as perirhinal and entorhinal cortical inputs (Lang and Pare, 1997), drive BLA projection neurons. Although these inputs also excite inhibitory interneurons (Lang and Pare, 1997),
the excitation on interneurons is smaller in magnitude than on
projection neurons (Rosenkranz and Grace, 2001), and furthermore, the
temporal EPSP/IPSP sequence is such that inhibition occurs after BLA
projection neurons are given the opportunity to fire (Fig. 5). It is
clear that differences observed between mPFC- and Te3-evoked PSPs do
not reflect the effects of cortically evoked PSPs on different sets of
BLA projection neurons, because our previous study (Rosenkranz and
Grace, 2001) demonstrated that mPFC stimulation will also suppress BLA
neurons that receive Te3 inputs. Thus, the effects uncovered in this
study provide a mechanism by which mPFC inputs inhibit BLA spontaneous
and Te3-driven activity. This effect of mPFC inputs is not observed in
all regions, because mPFC-evoked responses recorded from striatal
neurons are excitatory.
It is important to note that the normal function of the mPFC is likely
to be more complex than a simple inhibition of behavior. By stimulating
the mPFC, we are likely to activate a large population of fibers that
probably does not reflect the typical output of this system. In
contrast, it is possible that clusters of mPFC neurons fire together
during the course of PFC-related tasks, causing a selective inhibition
to a subpopulation of BLA output neurons. The mPFC would thereby play a
role in the selection of the appropriate affective behavior. However,
in exceptional circumstances a large degree of mPFC-BLA axons may be
activated, resulting in suppression of all affective behavior.
Similarly, the role of the mPFC is not limited to the BLA, and
afferents to association sensory cortical areas, for
example, may select what sensory information reaches the BLA.
Therefore, the interactions between the mPFC and the BLA are likely to
be highly complex when considered in the context of ongoing behavior.
In addition, it is unclear what relationship other regions of
the mPFC (i.e., orbitofrontal and cingulate cortices) have with
the BLA.
Modulation of neuronal excitability and spontaneous events
by DA
Activation of DA receptors enhanced BLA neuronal excitability and
suppressed spontaneous PSPs. Initially, this would appear paradoxical,
because increases in input resistance would lead to amplification of
PSP size. However, only somatic excitability is measured with the
methods used here, and the suppressive actions of DA may be limited to
dendrites (Herrling and Hull, 1980; Yang and Seamans, 1996; Hoffman and
Johnston, 1999) or may be presynaptic in nature (Hsu et al., 1995; Behr
et al., 2000). In contrast, the excitatory actions of DA are likely to
be postsynaptic effects for at least two reasons. First, some neurons
displayed delayed rectification in response to current injection. This
delayed rectification was removed by DA receptor activation, indicating
that DA suppresses somatic potassium conductances. Second, evoked PSPs
often displayed a sublinearity when examined as a function of membrane
potential. DA receptor activation linearized this relationship, again
indicative of a suppressive action of DA on somatic voltage-dependent
potassium conductances that reduce PSP amplitude. Furthermore, it has
been reported that DA reduces a slow inhibitory potential mediated by a
postsynaptic calcium-activated potassium conductance (Danober and Pape,
1998). The increases in neuronal excitability are not the indirect
result of decreased spontaneous PSPs, as demonstrated by the data
indicating that our measurement of input resistance was not correlated
with SD, and the magnitude of the increases in input resistance after
DA receptor activation was not correlated with the magnitude of the
changes in SD. Furthermore, DA D2 receptor activation enhanced input
resistance without significant alterations of spontaneous PSP amplitude.
The spontaneous PSPs modulated by DA receptor manipulations are
probably of synaptic origin. Thus, their amplitude is dependent on the
membrane potential, but no evidence was seen for a voltage dependence
of their frequency. The reversal potential of these events as a whole
(approximately 25 mV) is between the reversal potential for chloride
and sodium, indicating that they may be a combination of glutamatergic
and GABAergic events. This is supported by the demonstration that a
portion, but not all, of these events reverse close to 65 mV.
Furthermore, it is expected that even if these events were entirely
glutamatergic in nature, the reversal potential would still be shifted,
because the majority of excitatory inputs are to more distally located
spines. Thus, altering somatic membrane potential by current injection
is not likely to cause an equivalent change at distal dendritic
regions, in contrast to the proximally located GABAergic inputs.
Differential modulation by DA receptor subtypes
The actions of DA on spontaneous PSPs, which may be presynaptic or
dendritic, appear to be mediated by the DA D1 receptor, whereas
alterations of somatic excitability are mediated by the DA D2 receptor.
As a consequence, DA would be expected to suppress spontaneous or
weaker signals by DA D1 activation, while enhancing large, coordinated
inputs via D2 receptor stimulation. Furthermore, DA D1 receptor
activation attenuates mPFC-evoked inhibition of BLA projection neurons.
Removal of this inhibition will further enhance the response to
nonattenuated inputs via a postsynaptic effect of DA.
It is unclear how DA receptor activation suppresses the majority of
spontaneously occurring PSPs yet enhances Te3-evoked responses. One
possibility is that the majority of spontaneously occurring PSPs are
the result of mPFC inputs, suggesting that, at least in the
anesthetized rat, inputs from Te3 do not appear to provide a tonic
input to this system. Alternatively, the DA D1 agonist may indirectly
affect activity within Te3.
The results described above demonstrate that, and provide a mechanism
by which, mPFC inputs exert a qualitatively different action on BLA
projection neurons when compared with inputs from Te3. Furthermore, DA
D1 and D2 receptors exert actions that would appear to counterbalance
each other with respect to effects on general excitability. However,
from a functional standpoint, DA D1 receptors suppress mPFC-evoked
inhibition to such a degree that DA D2-mediated enhancement of neuronal
excitability is negated with regard to this input. This would allow DA
D2 receptor stimulation to selectively enhance other inputs, such as
those arising from Te3.
Functional consequences
These data support our hypothesis that mPFC inputs inhibit BLA
projection neurons and thus suppress BLA-mediated behaviors by the recruitment of inhibitory BLA interneurons. In this manner, limbic inputs appear to exert a suppressive effect over sensory-evoked emotional responses. In contrast, DA receptor stimulation exerts effects in an opposite direction; this type of stimulation
enhances BLA output by (1) a presynaptic removal of mPFC-evoked
inhibition and (2) a postsynaptic enhancement of neuronal excitability
that amplifies sensory-related inputs, thereby amplifying affective responses to sensory stimuli. DA appears to allow an animal to make a
transition to a state in which affective behavior is driven by salient
sensory stimuli. Lending support to this hypothesis is the observation
that DA is released in the BLA in the presence of affective or
stressful stimuli (Coco et al., 1992; Hori et al., 1993; Inglis and
Moghaddam, 1999) and is necessary for the production of a BLA-dependent
response to these stimuli (Lamont and Kokkinidis, 1998; Guarraci et
al., 1999; Greba and Kokkinidis, 2001; Greba et al., 2001; Guarraci et
al., 2000; See et al., 2001). Furthermore, artificial elevations of DA,
such as those that occur after amphetamine or cocaine administration,
also result in inappropriate BLA-mediated affective behaviors (Willick
and Kokkinidis, 1995; Harmer et al., 1997; Harmer and Phillips,
1999a,b). Indeed, an emotional reaction to nonsalient sensory stimuli
in the absence of PFC-induced suppression could be interpreted as a
type of "paranoia," an effect often associated with amphetamine
administration (Angrist and Gershon, 1970; Janowsky and Risch, 1979;
Hall et al., 1988).
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FOOTNOTES |
Received Aug. 13, 2001; revised Sept. 28, 2001; accepted Oct. 8, 2001.
This work was supported by National Institutes of Health Grants
MH57440, MH45156 (A.A.G.), and MH12533 (J.A.R.). We thank Nicole
MacMurdo, Christy Wyant, and Brian Lowry for excellent technical
assistance. We also thank Dr. Anthony R. West for enlightening discussions.
Correspondence should be addressed to J. Amiel Rosenkranz,
Department of Neuroscience, 446 Crawford Hall, University of
Pittsburgh, Pittsburgh, PA 15260. E-mail: rosenk{at}bns.pitt.edu.
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ABSTRACT
INTRODUCTION
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