Division of Biological Sciences, University of Missouri, Columbia, Missouri 65211
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ABSTRACT |
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Zhou, Xiaoming and Philip H.-S. Jen. Brief and Short-Term Corticofugal Modulation of Subcortical Auditory Responses in the Big Brown Bat, Eptesicus fuscus. J. Neurophysiol. 84: 3083-3087, 2000. Recent studies show that the auditory corticofugal system modulates and improves ongoing signal processing and reorganizes frequency map according to auditory experience in the central nucleus of bat inferior colliculus. However, whether all corticofugally affected collicular neurons are involved in both types of modulation has not been determined. In this study, we demonstrate that one group (51%) of collicular neurons participates only in corticofugal modulation of ongoing signal processing, while a second group (49%) of collicular neurons participates in both modulation of ongoing signal processing and in reorganization of the auditory system.
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INTRODUCTION |
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The processing of auditory
information carried by complex sounds has been explained by neural
interactions based on divergent and convergent projections within the
ascending auditory system, but without considering the contribution of
the descending (corticofugal) auditory system (Suga
1997). However, recent studies have shown that the massive
corticofugal system, which is topographically as well-organized as the
ascending system (Games and Winer 1988
; Herbert
et al. 1991
; Huffman and Henson 1990
;
Saldaña et al. 1996
), extensively adjusts and
improves subcortical auditory signal processing in the frequency, time,
and spatial domains (He 1997
; Jen and Zhang
1999
; Jen et al. 1998
; Suga et al.
1997
; Sun et al. 1989
, 1996
;
Villa et al. 1991
; Yan and Suga 1996
,
1998
; Zhang and Suga 1997
; Zhang
et al. 1997
). These corticofugal modulations are based on
highly focused positive feedback to subcortical neurons "matched"
in tuning to a particular acoustic parameter and widespread negative
feedback (lateral inhibition) to "unmatched" subcortical neurons.
The corticofugal system also contributes to the reorganization (plasticity) of subcortical sensory maps, according to sensory experience including associative learning (Gao and Suga
1998
; Yan and Suga 1998
). However, these studies
did not explore whether these two types of corticofugal modulation were
mediated through the same or different groups of subcortical auditory neurons.
Using the big brown bat, Eptesicus fuscus, as a mammalian model, we report here that one group of neurons in the central nucleus of the inferior colliculus (IC) participates only in corticofugal modulation of ongoing signal processing while another group of collicular neurons additionally participates in corticofugal reorganization of the auditory system.
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METHODS |
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One or two days before the recording session, a 1.8-cm nail was
glued onto the exposed skull of each of nine pentobarbital sodium
(Nembutal)-anesthetized (45-50 mg/kg body wt) bats (body wt 20-24
g). During recording, each bat was administered the neuroleptanalgesic Innovar (0.08 mg/kg body wt of fentanyl, 4 mg/kg body wt of
droperidol) and was strapped to an aluminum plate with transparent
plastic sheeting inside a double-wall, sound-proof room (temperature
28-30°C). The bat's head was immobilized by fixing the shank of the
nail into a metal rod with a set screw (Suga and Schlegal
1972). Small holes were then bored in the skull above the
primary auditory cortex (AC) and the IC.
Acoustic stimuli (4 ms with 0.5 ms rise-decay times at 2 pps) were generated with an oscillator (KH model 1200) and a homemade electronic switch. These stimuli were then amplified after passing through a decade attenuator (HP 350D) before they were fed to a small condenser loudspeaker (AKG model CK 50, 1.5 cm diam, 1.2 g) that was placed 23.5 cm away from the bat and at 40° contralateral to the recording site. The loudspeaker was calibrated with a Brüel and Kjaer 1/4-in. (4135) microphone placed at the bat's head. The output was expressed in dB SPL in reference to 20 µPa root mean square.
During experiments, custom-made, two tungsten-in-glass electrodes,
described previously (Jen et al. 1998) (tip: <10 µm,
inter-tip distance: 30-50 µm), were inserted into the AC at depths
of 500-700 µm (the 5th layer of the AC) (Jen et al.
1997
). When a single neuron was isolated, the frequency
and intensity of the sound were systematically varied to determine the
best excitatory frequency (BFAC) at which the
neuron had the lowest threshold to sound stimulus (i.e., the minimum
threshold or MTAC). At the
MTAC, the neuron responded to each of two
consecutive presentations of BFAC pulses. The
neuron's latencyAC to a
BFAC sound at 10 dB above the
MTAC was determined. A 3 M KCl glass micropipette
electrode (diameter 1 µm, impedance 5-10 M
) was then used to
record auditory response of neurons in the central nucleus of the IC
ipsilateral to the AC. After determining the
BFIC, the MTIC, and the
latencyIC of each isolated collicular neuron, a
BFIC sound at 10 dB above the MTIC (abbreviated as ASIC),
was used to obtain the neuron's response (i.e., the control response).
Then the same BFIC sound was delivered together
with an electrical stimulation (4-ms train stimulus consisting of 4 monophasic pulses of 0.1 ms at 2 trains/s) in the AC (abbreviated as
ESAC) to obtain the collicular neuron's
responses (referred to as ASIC + ESAC stimulation conditions). When the neuron's
response was affected by ESAC, the interval
between ESAC and ASIC was
adjusted (1-6 ms, usually 1-3 ms) such that the neuron's response
was either decreased or increased at least 20%. The electrical current
(5-50 µA, usually 5-25 µA) that produced a 30-50% change in
response relative to the control response was then chosen for
subsequent experiments.
To determine whether corticofugal modulation of the response of a
collicular neuron had different time courses, the neuron's response
was monitored under two stimulation conditions. First, the responses of
each corticofugally affected collicular neuron to
ASIC alone and to ASIC + ESAC were monitored when the
ESAC was delivered at 2 trains/s. The neuron's
response to ASIC was also monitored on cessation
of ESAC and at 5-min intervals for 35 min
thereafter. Second, an ESAC at 10 trains/s and a
BFAC sound at 10 dB above the
MTAC was delivered for 30 min (referred to as
ASAC + ESAC stimulation
conditions). The neuron's response to ASIC was
then monitored on cessation of ASAC + ESAC and at 5-min intervals for 35 min
thereafter. This ASAC + ESAC stimulation condition was comparable to the
one used in previous studies that produced short-term corticofugal
modulation (Gao and Suga 1998; Yan and Suga
1998
).
Recorded action potentials were amplified with conventional techniques and sent to a computer (Gateway 2000, 486) for acquisition of peristimulus time histograms (binwidth: 500 µs, sampling period: 100 ms) of the neuron's responses to 32 stimuli. The total number of impulses in each histogram was used to quantify the neuron's response under each stimulation condition.
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RESULTS |
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In this study, 30 corticofugally inhibited and 9 corticofugally facilitated collicular neurons were isolated. The effect of corticofugal modulation in 20 (51%, 16 corticofugally inhibited and 4 facilitated) collicular neurons vanished within 5-10 s following cessation of either ASIC + ESAC or ASAC + ESAC. For convenience, this type of corticofugal modulation is called brief corticofugal modulation. In contrast, the effect of corticofugal modulation in the remaining 19 (49%, 14 corticofugally inhibited and 5 facilitated) collicular neurons persisted up to 5-35 (average 20 ± 9.0) min following cessation of ASAC + ESAC. This type of corticofugal modulation is called short-term corticofugal modulation.
Figure 1 shows the discharge pattern, the number of impulses, MTIC and latencyIC of a representative corticofugally inhibited collicular neuron that displayed both brief and short-term corticofugal modulation. This neuron discharged a total of 81 or 82 impulses to ASIC (the control response). During ASIC + ESAC, the neuron's number of impulses decreased from 81 (Fig. 1Aa) to 41 (Fig. 1Ab). The number of impulses increased to 76 following cessation of ASIC + ESAC and was between 76 and 80 when monitored up to 25 min thereafter (Fig. 1A, c-h). In contrast, the neuron's number of impulses decreased from 82 to 39 (Fig. 1A, i-j) and slowly returned to within 5% of the control level over a period of 35 min following ASAC + ESAC (Fig. 1A, j-q). Figure 1, B-D, shows the time course of both brief and short-term corticofugal modulation on the neuron's auditory responses. Variation in the number of impulses (in percent change), the MT and the latency during ASIC + ESAC (Fig. 1, B-D, filled triangles) returned to within 5% of the control level (Fig. 1, B-D, open triangles) on cessation of ASIC + ESAC and remained at the same level even when monitored for 25 min thereafter (Fig. 1, B-D, open circles). However, variations in the neuron's responses only gradually returned to within 5% of the control level over a period of 35 min after ASAC + ESAC (Fig. 1, B-D, filled circles).
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Figure 2 shows both brief and short-term corticofugal modulation in the auditory response of a representative corticofugally facilitated collicular neuron. This neuron discharged a total of 45 or 46 impulses to ASIC. During ASIC + ESAC, the neuron's number of impulses increased from 45 (Fig. 2Aa) to 64 (Fig. 2Ab). The number of impulses decreased to 48 on cessation of ASIC + ESAC (Fig. 2Ac) and was between 44 and 48 within the subsequent 25 min (Fig. 2A, d-h). In contrast, the number of impulses increased from 46 to 70 (Fig. 2Aj) and did not return to within 2% of the control level until 25 min after ASAC + ESAC (Fig. 2Ao). Variation in the number of impulses, the MT, and the latency during ASIC + ESAC (Fig. 2, B-D; filled vs. open triangles) returned to within 5% of the control level after ASIC + ESAC and remained at the same level when monitored for 25 min thereafter (Fig. 2, B-D, open circles). However, the neuron's varied responses only gradually returned to within 5% of the control level over a period of 25 min after ASAC + ESAC (Fig. 2, B-D, filled circles).
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Figure 3 shows responses of corticofugally inhibited (Fig. 3, A1-A3) and corticofugally facilitated (Fig. 3, B1-B3) collicular neurons that were involved only in brief corticofugal modulation. Their responses returned to within 5% of the control level (Fig. 3, filled vs. open triangles) after both ASIC + ESAC and ASAC + ESAC. These two neurons had similar recovery time course for both stimulation conditions (Fig. 3, open vs. filled circles).
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Previous studies (Gao and Suga 1998; Yan and Suga
1998
) reported that ASAC + ESAC produced an asymmetrical
BFIC shift toward BFAC when
BFIC was within 10 kHz above the
BFAC and the maximal BFIC
shift occurred when the BFAC-IC difference
between cortical and cortical neurons was ~5 kHz. Among 19 neurons
that were involved in both brief and short-term corticofugal
modulation, the BFICs of four corticofugally
inhibited and three corticofugally facilitated collicular neurons were
above the BFAC by 0.23-2.91 kHz.
ASAC + ESAC produced a
BFIC shift toward to BFAC
in two neurons with BFIC above the corresponding
BFAC by 1.91 and 2.91 kHz. However, the
BFIC shifts due to ASAC + ESAC in five other neurons were too small to
determine confidently.
We examined the BFAC-IC difference in relation to brief and short-term corticofugal modulation. As shown in Table 1, BFAC-IC difference was significantly larger in collicular neurons that were only involved in brief corticofugal modulation (e.g., Fig. 3) than in collicular neurons that were involved in both types of corticofugal modulation (e.g., Figs. 1 and 2; t-test, P < 0.001). Although not significant, BFAC-IC difference within each group of collicular neurons was smaller for corticofugal facilitation than for corticofugal inhibition (t-test, P > 0.05).
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DISCUSSION |
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Our finding of brief corticofugal modulation confirms that the
corticofugal system can actively modulate collicular responses through
inhibition (Fig. 1A, b-h, and B-D, open
circles) and facilitation (Fig. 2A, b-h, and
B-D, open circles) to improve ongoing signal processing. We
found that short-term modulation of collicular responses (e.g., Figs. 1
and 2, Aj-Aq, and B-D, filled
circles) persisted for 5-35 (average 20 ± 9.0) min after
ASAC + ESAC. Variation in
the number of impulses, the MT, and the latency during this time period
suggests a plastic change in collicular auditory sensitivity. This
finding supports earlier studies (Gao and Suga 1998;
Yan and Suga 1998
) that the corticofugal system
contributes to neuroplasticity in the sensory system.
We have shown that one group of collicular neurons participated in both brief and short-term modulation (Figs. 1 and 2) and the other group participated only in brief corticofugal modulation of collicular signal processing (Fig. 3). The BFAC-IC difference in these two groups of collicular neurons was significantly different (Table 1). Future work is needed to determine whether these two groups of collicular neurons have different neural pathways for corticofugal modulation.
As described earlier, many recent studies (He 1997;
Jen and Zhang 1999
; Jen et al. 1998
;
Suga et al. 1997
; Sun et al. 1989
, 1996
; Yan and Suga 1996
,
1998
; Zhang and Suga 1997
; Zhang
et al. 1997
) have shown that the effect of corticofugal
modulation can either be very brief or last for more than 3 h on
cessation of ESAC. Furthermore, corticofugal
modulation of sensory maps due to classical conditioning may last for
periods ranging from 3 h to 8 wk (Weinberger et al.
1993
). In this study, we used brief and short-term modulation
to respectively describe a corticofugal modulation that vanished within
5-10 s or persisted up to 5-35 min following cession of
ESAC (Figs. 1 and 2, Aa-Ah, and
Ba, Ca, and Da; and Fig. 3). To avoid confusion
when comparing studies of auditory corticofugal modulation in the
future, we propose that short-term modulation includes corticofugal
modulation that lasts up to 3 h. We also propose that long-term
modulation be used to describe corticofugal modulation associated with
classical conditioning experiments, which lasts for more than 3 h.
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ACKNOWLEDGMENTS |
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We thank Dr. A. Chandrasekhar and two anonymous reviewers for commenting on an earlier version of the manuscript.
This work was supported by National Science Foundation Research Grant NS9907610. The experiments were conducted in compliance with National Institutes of Health Publication No. 85-23, "Principles of Laboratory Animal Care" and with the approval of the Institutional Animal Care and Use Committee (#1438) of the University of Missouri Columbia.
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FOOTNOTES |
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Address for reprint requests: P.H.-S. Jen (E-mail: jenp{at}missouri.edu).
Received 10 April 2000; accepted in final form 31 July 2000.
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REFERENCES |
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