Department of Biology, Washington University, St. Louis, Missouri 63130
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ABSTRACT |
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Ma, Xiaofeng and Nobuo Suga. Plasticity of Bat's Central Auditory System Evoked by Focal Electric Stimulation of Auditory and/or Somatosensory Cortices. J. Neurophysiol. 85: 1078-1087, 2001. Recent findings indicate that the corticofugal system would play an important role in cortical plasticity as well as collicular plasticity. To understand the role of the corticofugal system in plasticity, therefore, we studied the amount and the time course of plasticity in the inferior colliculus (IC) and auditory cortex (AC) evoked by focal electrical stimulation of the AC and also the effect of electrical stimulation of the somatosensory cortex on the plasticity evoked by the stimulation of the AC. In adult big brown bats (Eptesicus fuscus), we made the following major findings. 1) Electric stimulation of the AC evokes best frequency (BF) shifts, i.e., shifts in frequency-response curves of collicular and cortical neurons. These BF shifts start to occur within 2 min, reach a maximum (or plateau) at 30 min, and then recover ~180 min after a 30-min-long stimulus session. When the stimulus session is lengthened from 30 to 90 min, the plateau lasts ~60 min, but BF shifts recover ~180 min after the session. 2) The electric stimulation of the somatosensory cortex delivered immediately after that of the AC, as in fear conditioning, evokes a dramatic lengthening of the recovery period of the cortical BF shifts but not that of the collicular BF shift. The electric stimulation of the somatosensory cortex delivered before that of the AC, as in backward conditioning, has no effect on the collicular and cortical BF shifts. 3) Electric stimulation of the AC evokes BF shifts not only in the ipsilateral IC and AC but also in the contralateral IC and AC. BF shifts are smaller in amount and shorter in recovery time for contralateral collicular and cortical neurons than for ipsilateral ones. Our findings support the hypothesis that the AC and the corticofugal system have an intrinsic mechanism for reorganization of the IC and AC, that the reorganization is highly specific to a value of an acoustic parameter (frequency), and that the reorganization is augmented by excitation of nonauditory sensory cortex that makes the acoustic stimulus behaviorally relevant to the animal through associative learning.
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INTRODUCTION |
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The auditory, visual, and
somatosensory systems, respectively, have cochleotopic, retinotopic,
and somatotopic maps in their central neural pathways. These sensory
epithelial maps are modified by deprivation, injury, and experience in
young and adult animals (Clark et al. 1988; Gao
and Suga 1998
, 2000
; Hubel et al. 1977
; Irvine and Rajan 1996
; Jenkins et al.
1990
; Kaas et al. 1990
; Merzenich et al.
1984
; Pettet and Gilbert 1992
; Recanzone
et al. 1993
; Snyder et al. 1990
, 1991
;
Weinberger et al. 1993
). Such plasticity has been
explained by changes in divergent and convergent projections of neurons
in the ascending sensory system. However, recent findings indicate that
the cerebral sensory cortex and the descending (corticofugal) system
play an important role in plasticity. In the motor (Nudo
et al. 1996
), somatosensory (Recanzone et al.
1993
; Spengler and Dinse 1994
), and auditory
systems (Chowdhury and Suga 2000
; Maldonado and
Gerstein 1996
; Yan and Suga 1996
, 1998
;
Zhang et al. 1997
), focal electrical stimulation of a
particular portion of the sensory or motor map in the cortex evokes
changes in the cortical map around the stimulated portion and also in the subcortical map corresponding to the cortical map where changes are evoked.
Recent studies indicate that cortical neurons of the mustached bat
(Pteronotus parnellii) mediate, via corticofugal projection, a highly focused positive feedback to subcortical neurons "matched" in the tuning of a particular acoustic parameter and a widespread lateral inhibition to "unmatched" subcortical neurons. This
function, named egocentric selection, improves the neural
representation of frequently occurring signals in the central auditory
system (Yan and Suga 1996; Zhang and Suga
1997
). In the big brown bat, Eptesicus fuscus,
egocentric selection shifts the best frequencies (BFs) of collicular
neurons not only toward the BF of electrically stimulated cortical
neurons but also toward the frequency of a repetitively delivered
acoustic stimulus (tone burst). BF shifts mean a reorganization of the
frequency map in the inferior colliculus: IC (Yan and Suga
1998
). Focal electric stimulation of the auditory cortex (AC)
also evokes reorganization of the cortical frequency map
(Chowdhury and Suga 2000
). However, the time courses of
collicular and cortical BF shifts have not yet been studied. The first
aim of the present studies was to measure the time courses of
collicular and cortical BF shifts evoked by focal electric stimulation
of the AC.
The somatosensory cortex plays an essential role in plasticity of the
IC (Gao and Suga 1998) and the AC (Gao and Suga
2000
) evoked by fear conditioning with acoustic stimuli
followed by electric leg stimulation. Inactivation of the somatosensory
cortex during the conditioning blocks both collicular and cortical BF shifts that otherwise would be evoked by the conditioning. The second
aim of the present studies was to investigate whether electric stimulation of the somatosensory cortex following electric stimulation of the AC augments collicular and cortical BF shifts.
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METHODS |
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Materials, surgery, recording of neural activity, acoustic
stimulation, cortical electrical stimulation, data acquisition, and
data processing were basically the same as those described in
Yan and Suga (1996) and Chowdhury and Suga
(2000)
. Therefore only the essential portion of the methods are
summarized in the following text. Fifteen adult big brown bats (body
weight: 18-24 g) were used for the present experiments. Under
neuroleptanalgesia (fentanyl-droperidol mixture, 4.08 mg/kg
body wt), a 1.5 cm-long metal post was glued on the dorsal surface of
the bat's skull. The physiological experiment was started 3-4 days
after the surgery. The animal was placed in a polyethylene-foam body
mold and was hung at the center of a sound-proof room that was
maintained at 31°C. The bats used were neither anesthetized nor
tranquilized. They were not going into hibernation. The temperature
monitored with a thermistor placed between the bat and body mold was
37°C. The metal post mounted on the skull was fixed on a metal rod
with set screws to immobilize the animal's head, and the bat's head was adjusted to face directly at a loudspeaker located 74 cm away. Holes 50-100 µm in diameter were made in the skull covering the AC
or the inferior colliculus (IC). Tungsten-wire electrodes for recording
action potentials or for electrically stimulating cortical neurons were
inserted into the brain through these holes (see following text). The
bats were monitored on a video monitor screen during the experiments.
The protocol for this research was approved by the animal studies
committee of Washington University.
Acoustic stimulation
Acoustic stimuli were 20-ms-long tone bursts with a 0.5-ms rise-decay time. They were generated by a voltage-controlled oscillator and an electronic switch and were delivered at a rate of 5/s with a leaf tweeter. The frequency and amplitude of the tone bursts were varied manually or computer-controlled. The amplitude was calibrated with a Bruel and Kajael microphone and was expressed in dB SPL.
The frequency-tuning curve of a single collicular or cortical neuron
was first manually measured. Then the amplitude of a tone burst was
fixed at 10 dB above minimum threshold of the neuron, and a
computer-controlled frequency scan was delivered. [A
frequency-threshold or -tuning curve indicates that threshold varies as
a function of the frequency of sound. The lowest threshold of a
frequency-tuning curve has been called minimum threshold (Suga 1964).]
The frequency scan consisted of 21 time blocks. In the first 20 blocks,
frequency was changed in 0.3- or 0.5-kHz steps, and in the 21st (last)
block, no stimulus was presented to count background discharges. The duration of each block was 200 ms, so that the duration of the frequency scan was 4,200 ms. An identical frequency scan was repeated 50 times, and the responses of a single neuron were displayed as an
array of peri-stimulus-time (PST) histograms or PST cumulative (PSTC)
histograms (Figs. 1 and 2).
Electrical stimulation
Electrical stimuli were delivered through a pair of
tungsten-wire electrodes, the tips of which were 6-8 µm in diameter
and were separated by 150 µm, one proximal to the other. These
electrodes were used first to record auditory responses of cortical
neurons at the depths of 200-900 µm, i.e., at cortical layers
III-VI, then to measure the BF and minimum threshold of these neurons, and finally to electrically stimulate them. The electrical stimulation was a 6-ms-long train of four monophasic electric pulses (100 nA,
0.2-ms duration, 2.0-ms interval). The train of electric stimuli was
delivered at a rate of 10/s for 2-90 min (hereafter,
ESar). The train of 0.2-ms-long, 100-nA electric
pulses was estimated to stimulate neurons within a 60-µm radius
around the electrode tip (Yan and Suga 1996). Therefore
electrical stimulation of the AC is quite focal. The bat showed no
behavioral response at all to such a weak electrical stimulation
delivered to the AC.
To mimic trace conditioning with a train of tone pulses followed by an electric leg stimulation, a train of electric stimuli delivered to the AC (hereafter ESat) was paired with an electric stimulation of the primary somatosensory cortex (hereafter ESs). ESat was 1.0 s long and consisted of 33 trains. Each train was 6 ms long and consisted of four electric pulses, as in ESar. ESat was delivered twice per minute for 30 min. ESs was 50 ms long and consisted of 20 0.2-ms-long, 100-µA electric pulses. It was also delivered twice per minute for 30 min. When paired, ESs was delivered 1.0 s after ESat. To mimic backward conditioning, ESs was delivered 1.0 s before ESat.
Data acquisition and processing
Cortical responses were recorded at depths between 200 and 600 µm. The central nucleus of the IC is big and shows a simple and
systematic tonotopic organization (Casseday and Covey
1992). The dorsal surface of the IC is directly visible
through the skull. In dorsoventral electrode penetrations through the
dorsal surface, the electrode passed across the main nucleus of the IC
so that BFs of neurons systematically became higher exactly as expected from the tonotopic map (e.g., Yan and Suga 1998
). The
neurons were recorded at depths between 200 and 2,000 µm in the
central nucleus of the IC.
The responses of a neuron to tone bursts in the frequency scan repeated 50 times were recorded before, during, and after ESar, ESat + ESs or ESs + ESat and were displayed as arrays of PST or PSTC histograms. The waveform of an action potential was stored on a digital storage oscilloscope at the beginning of the data acquisition and was used as a template. Action potentials discharged by the neuron were continuously monitored together with the template on the screen of the digital storage oscilloscope during data acquisition: before, during, and after the cortical stimulation. Data acquisition was continued as far as action potentials visually matched the template. Data were stored on a hard drive of a personal computer and were used for off-line analysis.
Off-line data processing included plotting PST or PSTC histograms displaying responses of a collicular or cortical neuron to 50 identical acoustic stimuli and frequency-response curves based on 50 frequency scans obtained before, during, and after focal cortical stimulation. The magnitude of auditory responses was expressed by a number of impulses per 50 identical stimuli after subtracting background discharges counted in the last block of the frequency scan. A t-test was used to test the difference between the auditory responses obtained before and after the focal cortical stimulation and to test the difference between the responses of collicular and cortical neurons.
The following criteria were used for a shift in the frequency-response
curve or BF of a neuron evoked by a focal cortical stimulation. If a
shifted frequency-response curve or BF did not recover by 50%, the
data were excluded from the analysis. In stable long recording
conditions, all curves shifted by the cortical stimulation recovered by
50%. This recovery itself helped prove that the shift was
significant. When a BF shift was small and its significance was not
obvious, a weighted average frequency (i.e., BF) was calculated for the
summed responses to five consecutive frequency scans (Blaisdell
1993). Then the mean and standard deviation of these
weighted averages were computed, and a two-tailed paired t-test was used to determine whether or not the
weighted-average frequencies obtained for control and stimulus
conditions were significantly different for P < 0.05. The criterion for an increase or decrease in response magnitude (number
of impulses per 50 stimuli) was a change of 20% from a response
magnitude in a control condition, i.e., in a 20-min-long time period
immediately prior to electrical stimulation of the AC.
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RESULTS |
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Shifts in the best frequencies of collicular and cortical neurons evoked by focal electric stimulation of the AC
The effects of focal electric stimulation of the AC (ESar or ESat) were studied on the auditory responses of 257 collicular and 212 cortical ipsilateral neurons (469 in total) and on those of 31 collicular and 26 cortical contralateral neurons (57 in total). Since the great majority of neurons studied were ipsilateral to the cortical electric stimulation, they are simply called collicular or cortical neurons, while the small number of contralateral neurons studied are specified as contralateral collicular or cortical neurons. Of the 469 neurons studied, 193 collicular and 172 cortical neurons showed clear changes in response magnitude, frequency-response curve and BF for cortical electric stimulation. The data obtained from these 365 neurons are shown in the figures.
ESar as short as 2 min could evoke BF shifts in
the IC and AC. The amount of the BF shifts became larger with the
duration of ESar and became a maximum for a
30-min-long ESar. Figures
1 and 2 show changes in the responses
(A and B) and the frequency-response curve
(C) evoked by a 30-min-long ESar of a
collicular and a cortical neuron, respectively. The collicular neuron
in Fig. 1 was tuned to 31.5 kHz (C1, ). When the
ESar was delivered to cortical neurons tuned to
26.0 kHz, its frequency-response curve and BF shifted from 31.5 to 29.0 kHz at the end of the ESar (C2,
x), i.e., toward the BF of the electrically stimulated
cortical neurons. The shifted frequency-response curve and BF shifted
to 30.5 kHz 90 min after the ESar (C3,
x), and returned to 31.5 kHz 180 min after the
ESar (C4,
). The time for full
recovery from the maximum shift was ~180 min. Figure 1, A
and B, respectively show the changes in the responses to a
31.5 kHz (the BF in the control condition: BFc)
and a 29.0-kHz tone burst (the BF in the maximally shifted condition:
BFs). The ESar evoked a
decrease in the response at 31.5 kHz (A2) and an increase in
the response at 29.0 kHz (B2). In other words, the
corticofugal effect on the "unmatched" collicular neuron could be
inhibitory or facilitatory depending on the frequency. These
corticofugal effects disappeared 180 min after
ESar.
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The cortical neuron in Fig. 2 was tuned
to 40.0 kHz (C, ). When ESar was
delivered to 35.0-kHz tuned cortical neurons, its frequency-response
curve and BF shifted from 40.0 to 38.0 kHz at the end of the
ESar (C,
), i.e., toward the BF of
the electrically stimulated cortical neurons. The shifted
frequency-response curve and BF shifted back to 38.5 kHz 90 min after
the ESar (C,
), and returned to
40.0 kHz 180 min after the ESar (C,
- - -). That is, the time for full recovery was 180 min. Figure 2,
A and B, respectively, shows the changes in the
responses to a 40.0-kHz (BFc) and a 38.0-kHz tone
burst (BFs). The ESar
evoked an overall decrease in the response at 40.0 kHz (A2)
and an overall increase in the response at 38.0 kHz (B2).
Therefore the effect of ESar on the unmatched
cortical neuron could be inhibitory or facilitatory depending on the
frequency.
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BF shift for a 30- or 60-min-long ESar was
studied with 65 collicular neurons. Of the 65, 43 showed BF shifts
(Fig. 3A). The directions and
amounts of BF shifts of these neurons are represented by the directions
and lengths of bars originating from individual symbols, respectively.
Regardless of the BFs of electrically stimulated cortical neurons, 30 collicular neurons with a BF within a 10-kHz band immediately above the
BF of electrically stimulated cortical neurons (hereafter, cortical BF)
showed a downward BF shift without exception. Seven collicular neurons
with a BF within a 7-kHz band immediately below the cortical BF showed
an upward BF shift. Five collicular neurons with a BF within a band
10-15 kHz higher than the cortical BF also showed an upward BF shift
without exception. The amount of BF shift differed from neuron to
neuron. However, there was no sign that the higher the cortical BF, the
larger the collicular BF shift. To substantiate this, BF shifts in Fig. 3A are plotted as a function of cortical BF (Fig.
3B). In Fig. 3B, BF shifts of collicular neurons
with a BF 4-6 kHz higher than the cortical BF are shown with filled
symbols because it has been demonstrated that these collicular neurons
showed the largest BF shifts (Chowdhury and Suga 2000;
Yan and Suga 1998
). A 40- to 60-kHz band is one octave
higher than a 20- to 30-kHz band, and there are several data points in
each of these frequency bands. A comparison between the data in these
frequency bands indicates that there was no relationship such that
collicular BF shifts for 40- to 60-kHz cortical BFs were two times
larger than those for 20- to 30-kHz cortical BFs. The mean and SE of BF
shifts were 0.52 ± 0.20 kHz (n = 9) for 20-30
cortical BFs and 0.48 ± 0.14 kHz (n = 13) for 40- to 60-kHz cortical BFs. The difference between these two means is
statistically insignificant (P = 0.36). Therefore in
our present paper, BF shifts are expressed in kilohertz, not in octave.
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Figure 4 shows collicular BF shifts evoked by ESar's with different durations as a function of difference in BF between recorded collicular and stimulated cortical neurons. The duration of ESar was 15 (A), 30 (B), or 60 min (C). BF shift became larger with the duration of ESar. Regardless of the duration, however, the major BF shifts occurred for neurons with BFs within 10 kHz higher than the BF of electrically stimulated cortical neurons, and these were toward the cortical BF. The BF shifts toward the cortical BF may be defined as "centripetal" BF shifts, and those away from the cortical BF may be defined as "centrifugal" BF shifts. Since the major BF shifts occurred only on one side of the cortical BF, these were asymmetrical and centripetal. Minor BF shifts occurred for neurons with BFs ~5 kHz lower or ~13 kHz higher than the cortical BF. These were centripetal and centrifugal, respectively. The largest BF shifts occurred at 4-5 kHz above the cortical BF and were 1.6 kHz for the 15-min-long ESar and 2.0 kHz for both the 30 and 60 min-long ESar's.
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About half of the collicular and cortical neurons contralateral to the
AC stimulated by ESar showed no BF shift, but the
remaining half did (Fig. 5A).
Different from the ipsilateral collicular and cortical BF shifts, which
were asymmetrical and centripetal (Fig. 5B), the BF shifts
in the contralateral collicular and cortical neurons were somewhat
symmetrical and centripetal (Fig. 5A). Centripetal BF shifts
occurred for BFs that were within a range between 9 and +12 kHz of
the BFs of stimulated cortical neurons. The centripetal BF shifts were
sandwiched between centrifugal BF shifts that occurred for BFs that
were between
10 and
14 and between +13 and +17 kHz (Fig.
5A). For comparison in BF shift between the contralateral and ipsilateral neurons, Fig. 5B shows the BF shifts of
ipsilateral collicular and cortical neurons. It is clear that the BF
shifts in the ipsilateral neurons were asymmetrical and that the BF
shifts for BFs 5-8 kHz higher than the BF of electrically stimulated cortical neurons were much larger than those in the contralateral neurons.
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Time courses of BF shifts in ipsilateral collicular and cortical neurons
BF shift was largest for collicular and cortical neurons with a BF ~5 kHz higher than that of electrically stimulated cortical neurons (Fig. 4). Therefore the time courses of BF shifts were measured for collicular and cortical neurons with a BF ~5 kHz higher than the BF of the electrically stimulated cortical neurons.
Since stimulus artifacts interfered with the recording of action potentials, the duration of ESar was varied from 2 to 90 min and the amounts of collicular and cortical BF shifts were measured immediately after ESar. The BF shifts of collicular and cortical neurons were 0.6 ± 0.34 and 0.6 ± 0.33 kHz, respectively, for a 2-min-long ESar (shortest horizontal bar of Fig. 6). Those were 0.68 ± 0.31 and 0.72 ± 0.30 kHz for a 4-min-long ESar (2nd shortest horizontal bar). There was no significant difference in BF shift between collicular and cortical neurons (P > 0.05). In other words, the BF shifts of the collicular and cortical neurons developed at the same time and to the same amount until 4 min after the onset of ESar. As the duration of ESar increased, the BF shifts increased. The amount of increase was larger for the cortical neurons than for the collicular neurons: 1.18 ± 0.20 kHz in the AC and 1.10 ± 0.18 kHz in the IC for a 30-min-long ESar (5th horizontal bar) and 1.36 ± 0.19 kHz in the AC and 1.19 ± 0.21 kHz in the IC for a 60-min-long ESar (6th horizontal bar). The difference in BF shift between the cortical and collicular neurons was not significant (P > 0.05) 30 min after the onset of ESar but was significant 60 min after that (P < 0.05). The collicular BF shift was 1.10 ± 0.18 and 1.19 ± 0.21 kHz at 30 and 60 min, respectively, after the onset of ESar. This difference was insignificant (P > 0.05). Therefore the collicular BF shift reached a plateau value 30 min after the onset of ESar. The cortical BF shift was 1.18 ± 0.20 and 1.36 ± 0.19 kHz at 30 and 60 min, respectively, after ESar. This difference was significant (P < 0.05). The cortical BF shifts for a 90-min-long ESar were the same as those for the 60-min-long ESar: 1.36 ± 0.19 kHz for 60 min and 1.31 ± 0.26 kHz for 90 min. The cortical BF shift thus reached a plateau value between 30 and 60 min after the onset of ESar. In other words, the collicular and cortical BF shifts both reached plateaus within 60 min after the onset of the 90-min-long ESar, and the plateau value was 14% larger for the cortical BF shift than for the collicular BF shift (P < 0.05). The 2-min-long ESar evoked ~50% of the maximum collicular BF shift and ~44% of the maximum cortical BF shift.
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The recovery period differed according to the amount of BF shift.
Figure 7, A and B,
shows the recovery curves of the BF shifts of collicular and cortical
neurons, respectively. The recovery curves of the cortical BF shifts
were similar to those of the collicular BF shifts. For example, the
collicular and cortical BF shifts evoked by the 2-min-long
ESar recovered 45 min after the
ESar (Fig. 7, ). Those evoked by the
30-min-long ESar recovered 180 min after the
ESar (Fig. 7,
). The amounts and recovery
times of the collicular BF shifts were the same for the 30-, 60-, and 90-min-long ESar's. However, the amount of
cortical BF shift was slightly larger for the 60- and 90-min-long
ESar than for the 30-min-long
ESar. The recovery time of the cortical BF shift
was very similar for the 30-, 60-, and 90-min-long
ESar's (Fig. 7,
,
, and
,
respectively). There was a noticeable difference in a 50% recovery
time between the collicular and cortical BF shifts. For example, the
50% recovery time was 25 min for the collicular neurons, but 45 min
for the cortical neurons when ESar was 15 min
long (
). It was 60 min for the former but 120 min for the latter
when ESar was 30 min long (
). These
differences between the collicular and cortical BF shifts were
statistically significant (P < 0.005). Therefore
cortical neurons tended to maintain BF shift longer than collicular
neurons.
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Augmentation of collicular and cortical BF shifts by electrical stimulation of the somatosensory cortex
Asymmetrical and centripetal BF shifts of collicular and cortical
neurons can be evoked by conditioning the bat with a conditioned acoustic stimulus (a train of tone bursts) followed by an unconditioned electric leg stimulus. The primary somatosensory cortex and the AC are
both necessary for these BF shifts (Gao and Suga 1998, 2000
). Therefore a train of electric stimuli
(ESat) was delivered to the AC, and then a short
train of electric stimuli (ESst) was delivered to
the somatosensory cortex to evoke the excitation of these cortices,
which would be evoked by the conditioning.
ESat delivered at a rate of 2/min over 30 min was less effective in evoking collicular and cortical BF shifts than the 30-min-long ESar in which an electric stimulus was repetitively delivered at a rate of 10/s. Collicular (0.78 ± 0.30 kHz) and cortical BF shifts (0.79 ± 0.34 kHz) were very similar in amount, but different in recovery time: 60 versus 100 min at 50% recovery and 120 versus 150 min at full recovery (Fig. 8, curves a and b). When ESat was followed by ESst, the collicular BF shift became 12% larger and lasted 70 min longer at 50% recovery than that evoked by ESat alone (Fig. 8, curve c). ESst had a larger effect on cortical BF shift than on collicular BF shift. That is, the cortical BF shift became 31% larger and lasted 120 min longer at 50% recovery than that evoked by ESat alone (Fig. 8, curve d). These differences in the changes evoked by ESst between the collicular and cortical BF shifts were significant (P < 0.05 for amount and P < 0.001 for 50% recovery time).
|
Figure 9 shows the arrays of PSTC
histograms representing frequency-response curves of a single
collicular and a single cortical neuron. In Fig. 9A, the
collicular neuron was tuned to 36.0 kHz (A1). When
ESat stimulating 30.5-kHz tuned cortical neurons
was followed by ESst, the collicular BF shifted
from 36.0 to 34.0 kHz at the end of the 30-min-long delivery of
ESat + ESst
(A2). The shifted BF recovered to the BF in the control
condition 180 min after ESat + ESst (A4). In Fig. 9B, the
cortical neuron was tuned to 41.5 kHz (B1). When
ESat stimulating cortical neurons tuned to 37.0 kHz was paired with ESst for 30 min, its BF
shifted to 39.5 kHz at the end of ESat + ESst (B2). The shifted BF slowly recovered: 39.5 kHz 180 min after ESat + ESst (B4) and 41.5 kHz 300 min after
ESat + ESst
(B5). ESst lengthened the recovery
period of cortical BF shift, as unconditioned leg stimulation did
(Gao and Suga 1998, 2000
).
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When an unconditioned leg stimulation is delivered prior to a
conditioned acoustic stimulus, collicular and cortical BF shifts are
not evoked or not augmented (Gao and Suga 1998). To
mimic this backward conditioning, ESst was
delivered prior to ESat. The collicular and
cortical BF shifts evoked by ESat alone were not
augmented at all in magnitude by this ESst + ESat. However, they showed a tendency toward
longer recovery periods, although this was statistically insignificant,
P > 0.05 (Fig. 10). In
other words, the electrical stimulation of the somatosensory cortex prior to that of the AC was ineffective in evoking the augmentation of
BF shifts, the same as backward conditioning.
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ESst augmented collicular and cortical BF shifts evoked by ESat, as shown in Fig. 8. Therefore it was expected that ESst also augmented collicular and cortical BF shifts evoked by acoustic stimuli (tone bursts). A 1.0-s-long train of tone bursts (10-ms-long, 50 dB SPL, tone burst rate of 33/s; hereafter ASt) delivered at a rate of 2/s for 30 min evoked small collicular (0.38 ± 0.34 kHz; n = 20) and cortical BF shifts (0.42 ± 0.35 kHz; n = 18) in 38 neurons but not in the remaining 41 neurons studied. These BF shifts recovered rapidly: 45 min after the ASt for the collicular neurons and 60 min after the ASt for the cortical neurons (Fig. 11, a and b).
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When each ASt was followed by ESst, the collicular BF shift became 139% larger and lasted 60 min longer at 50% recovery than that evoked by ASt alone (Fig. 11, c). ESst had a larger effect on the cortical BF shift than on the collicular BF shift. That is, the cortical BF shift became 166% larger and lasted 120 min longer at 50% recovery than that evoked by ASt alone (Fig. 11, d). The full recovery of the BF shifts after ASt + ESst occurred at 130 min in the IC and 180 min in the AC. These differences between the collicular and cortical BF shifts evoked by ESst were significant (P < 0.01 for amount and P < 0.005 for 50% recovery time).
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DISCUSSION |
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Corticofugal modulation and plasticity of the central auditory system
Electric stimulation of the AC (ESar) evokes
collicular (Yan and Suga 1998; Zhang et al.
1997
) and cortical BF shifts (Chowdhury and Suga
2000
). As shown in Figs. 6 and 7, these collicular and cortical
BF shifts rapidly and simultaneously develop within 2 min after the
onset of ESar and reach a maximum ~30 min after the onset of a 30-min-long ESar. They recover
(return) to the control BF ~180 min after the cessation of the
ESar. For a 90-min-long ESar, the maximal BF shifts plateau ~60 min
after the beginning of ESar and then recover
~180 min after the cessation of ESar. The
cortical BF shift tends to recover slightly slower than the collicular
BF shift. However, both the collicular and cortical changes are short
term and similar to each other. The collicular and cortical BF shifts
evoked by ESar do not give us a cue as to whether
the cortical BF shift evokes the collicular BF shift or vice versa.
Gao and Suga (2000)
found that for auditory
conditioning, the collicular BF shift develops faster than the cortical
BF shift does and that the former can be evoked without the latter.
Therefore they hypothesized that the collicular change boosts the
cortical change.
The collicular BF shift evoked by a 30-min-long
ESar is similar in amount and time course to that
evoked by a 30-min-long conditioning session. Inactivation of the AC
during the conditioning evokes no collicular BF shift, which otherwise
would be evoked (Gao and Suga 2000). These findings
indicate that the collicular change evoked by the conditioning is based
on corticofugal modulation.
The cortical and collicular BF shifts evoked by
ESar are similar to each other in amount and time
course, as shown in Figs. 5-7. It recovers ~180 min after a 30- or
90-min-long ESar. However, the cortical and
collicular BF shifts evoked by the conditioning are quite different
from each other. That is, the cortical BF shift evoked by the
conditioning develops slowly, reaches a plateau when the collicular BF
shift is almost recovered, and lasts many hours after the conditioning
(Gao and Suga 2000). These data indicate that whether
the cortical BF shift follows the collicular BF shift depends on
nonauditory systems.
Inactivation of the somatosensory cortex during the conditioning
abolishes the collicular and cortical BF shifts, otherwise they would
be evoked. Therefore Gao and Suga (1998, 2000
)
hypothesized that the somatosensory cortex and the AC send
somatosensory and auditory signals, respectively, to the amygdala
through the association cortex and that this pathway is essential for
cortical plasticity due to fear conditioning rather than the pathway
from the multisensory thalamic nuclei to the amygdala proposed by
Weinberger (1990
, 1998
). Electrical stimulation of the
somatosensory cortex immediately after (not before)
ESar or acoustic stimulation augments cortical BF
shift in magnitude and, in particular, duration, as shown in Figs. 8,
9, and 11. Therefore our present data strongly favor for the hypothesis
proposed by Gao and Suga (1998
, 2000
).
Someone who reviewed our paper apparently had difficulty in believing in reorganization (plasticity) of the cochleotopic maps of the IC and AC. The reviewer considers that BF shifts were not a reorganization of the cochleotopic map and might be caused by nonneural phenomena and that reorganization is an idea not a fact, "until it is demonstrated that any of the changes listed below did not occur during the experiments, their hypothesis is not substantiated, and their speculation that there is a reorganization of the neural tissue is unwarranted." 1) The body temperature of the bat during the experiments might have dropped to be the same as the temperature of the sound-proof chamber maintained at ~31°C, and our data might be unrelated to normal brain function. 2) Electrical stimulation of the AC might have directly evoked changes in noncortical structures, i.e., glial elements or vasculature, which consequently might have evoked BF shifts. 3) Arousal of the animal might have evoked changes in the brain temperature that could affect the behavior of single neurons and might have evoked BF shifts. And 4) electrical stimulation of the AC might have changed the frequency tuning of cochlear hair cells and, accordingly, might have evoked BF shifts of collicular and cortical neurons.
The bats placed in the body mold were not going into hibernation and
were neither anesthetized nor tranquilized. The temperature of its skin
surface touching the body mold was 37°C during the experiments. The
bats were not experiencing an abnormally low body temperature.
Therefore the first assertion can be dismissed. Asymmetrical and
centripetal BF shifts of collicular and cortical neurons are evoked not
only by electrical stimulation of the AC (Chowdhury and Suga
2000; Yan and Suga 1998
; present paper) but also
by auditory conditioning with repetitive acoustic stimuli followed by
electric leg stimulation (Gao and Suga 1998
, 2000
) or by
repetitive acoustic stimuli without any electrical stimulation of the
AC (Gao and Suga 1998
; Yan and Suga
1998
). Therefore the second assertion can be dismissed.
Asymmetrical and centripetal BF shifts are highly specific to the BF of
cortical neurons electrically stimulated and are augmented by electric
stimulation of the somatosensory cortex following that of the AC by a
1.0-s gap. A change in brain temperature or blood flow that might be
caused by arousal cannot evoke such highly frequency-specific BF
shifts, so the third assertion may also be dismissed. Atropine applied
to the IC or AC has little effect on auditory responses,
frequency-tuning curves and BFs of collicular and cortical neurons.
However, it has prominent effects on the BF shifts of these neurons.
For example, atropine applied to the IC immediately prior to auditory
conditioning selectively abolishes collicular BF shifts that otherwise
would be evoked in the same amount as those evoked by cortical
electrical stimulation. It does not abolish cortical BF shifts (W. Ji,
E. Gao, and N. Suga, unpublished data). These observations
indicate that collicular and cortical BF shifts do not depend on
possible changes in cochlear hair cells and that the AC and IC have
plasticity for reorganization of the cochleotopic map. BF shifts of
collicular and cortical neurons (i.e., reorganization of the
cochleotopic map) are a fact. However, we don't yet know the neural
mechanisms for the BF shifts. The exploration of the neural mechanisms
for BF shifts will be a further step in our research.
Variation in BF shifts
In the big brown bat, ESar evoked
asymmetrical and centripetal BF shifts in the ipsilateral IC
(Yan and Suga 1998) (Fig. 4) and AC (Chowdhury
and Suga 2000
) (Fig. 5B) but symmetrical and centripetal BF shifts in the contralateral IC and AC (Fig.
5A). We don't know of any physiological and anatomical
basis for this difference. In the mustached bat,
ESar delivered to the DSCF area of the primary
auditory cortex evoked symmetrical and centrifugal BF shifts in the
ipsilateral IC and MGB (Zhang and Suga 2000
). However,
ESar delivered to the posterior division of the
primary auditory cortex of the mustached bat evoked somewhat
symmetrical and centripetal BF shift in the AC (Sakai et al.
2000
). The DSCF area is specialized for fine frequency analysis
of sound at ~61 kHz and has a radial frequency axis (Suga and
Jen 1976
; Suga and Manabe 1982
). The
FM-FM area of the AC of the mustached bat is a specialized area for
fine analysis of echo delays (O'Neill and Suga 1979
)
and has an echo-delay axis (Suga and O'Neill 1979
). ESar delivered to the FM-FM area evoked
symmetrical and centrifugal best echo-delay shifts in the IC
(Yan and Suga 1996
). The DSCF and FM-FM areas are very
large relative to the nonspecialized (i.e., ordinary) portion of the
primary auditory cortex of this species. Therefore Suga et al.
(2000)
hypothesized that centrifugal BF or best echo-delay
shifts are related to increasing contrast in neural representation of
echo frequency in the DSCF area or of echo delay in the FM-FM area,
respectively, and that centripetal BF shift is related to augmenting
neural representation of a signal in the ordinary area such as the
posterior division of the AC of the mustached bat and the AC of the big
brown bat. This hypothesis is supported by the data obtained by
Sakai et al. (2000)
. They delivered
ESar to the AC of the gerbil, Meriones
unguiculatus and found that ipsilateral cortical BF shift was
asymmetrical and centripetal, the same as in the big brown bat.
As discussed in the preceding text, ESar evoked
BF shifts that are significantly different between species and between
cortical areas of the same species. We don't yet know the anatomical
and physiological basis for this variation. Yan and Suga
(1998) pointed out that symmetrical and asymmetrical BF shifts
related to symmetrical and asymmetrical shape, respectively, of tuning
curves of neurons and that centrifugal and centripetal BF shifts are
related to sharp and broad tuning curves, respectively. Suga et
al. (2000)
hypothesized that corticofugal positive feedback and
negative feedback are respectively related to centripetal and
centrifugal BF shifts. Further physiological and anatomical studies of
the corticofugal system with different species of animals remain to be
performed to explore the neural basis of BF shifts.
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ACKNOWLEDGMENTS |
---|
We thank N. Laleman for comments on this paper.
This work was supported by a research grant from the National Institute on Deafness and Other Communication Disorders (DC-00175).
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FOOTNOTES |
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Address for reprint requests: N. Suga, Dept. of Biology, Washington University, One Brookings Dr., St. Louis, MO 63130.
Received 21 August 2000; accepted in final form 20 November 2000.
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REFERENCES |
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