Afferent Regulation of Inhibitory Synaptic Transmission in the Developing Auditory Midbrain

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The Journal of Neuroscience, March 1, 2000, 20(5):1912-1921

Afferent Regulation of Inhibitory Synaptic Transmission in the Developing Auditory Midbrain
Carmen Vale¹ and Dan H. Sanes¹^,²
¹ Center for Neural Science and ² Department of Biology, New York University, New York, New York 10003

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To determine whether afferent innervation regulates the strength of inhibitory connections in the gerbil auditory midbrain,both cochleas were surgically removed in postnatal day 7 animals,before sound-driven activity is first observed. Inhibitory synapticcurrents were measured in a brain slice preparation 1-7 d afterthe ablations. Whole-cell and gramicidin-perforated patch recordingswere obtained from inferior colliculus neurons, and IPSCs wereevoked by stimulation of the commissure of the inferior colliculus(CIC) or the ipsilateral lateral lemniscus (LL) in the presenceof kynurenic acid. Deafferentation led to a 24 mV depolarizingshift in the IPSC equilibrium potential within 1 d of deafferentation.As a consequence, there was a large reduction of IPSC amplitudeat a holding potential of $-$ 20 mV in neurons from bilaterally ablatedanimals. Furthermore, both afferent pathways displayed a 50% reductionof the inhibitory synaptic conductance after deafferentation,indicating that driving force was not solely responsible for thedecline in IPSC amplitude. When paired pulses were delivered tothe LL or CIC pathway in control neurons, the evoked IPSCs exhibitedfacilitation. However, paired pulse facilitation was nearly eliminatedafter deafferentation. Thus, normal innervation affects inhibitorysynaptic strength by regulating postsynaptic chloride homeostasisand presynaptic transmitter releaseproperties.

Key words: GABA_A receptor; glycine receptor; inferior colliculus; inhibitory; gerbil; deafness

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Spontaneous and evoked electrical activity play a critical role in the maturation of central neuronal circuits. Complete orpartial sensory deprivation can produce alterations at all levelsof the system, and these effects are most profound during earlydevelopment. For example, the loss or complete inactivation ofthe cochlea leads to the cessation of protein synthesis, cellshrinkage, dendrite retraction, and cell death in the chick auditorybrainstem (Parks, 1979; Deitch and Rubel, 1984; Born and Rubel,1988). To understand how alteration of synaptic architecture andprotein expression might affect synaptic processing, it is importantto learn the functional properties of these connections. Becausecentral neurons receive a rich array of excitatory, inhibitory,and modulatory afferents, it is necessary to study their responseto disuse on an individual basis. The present study examines theeffect of deafferentation on inhibitory afferents in the auditorymidbrain.

Use-dependent alterations of inhibitory synapses have been demonstrated in the developing and adult nervous system. When organotypiccultures of the mouse cerebellum are grown in tetrodotoxin toblock electrical activity, the number of inhibitory synapses isselectively reduced (Seil and Drake-Baumann, 1994). The regulationof inhibitory synaptic strength may derive, in part, from thestimulation of receptor synthesis and clustering by GABA and glycine(Poulter et al., 1997; Kirsch and Betz, 1998). Alternatively,the accumulation and release of transmitter may also be compromisedby changes in the level of activity (Hendry and Jones, 1986; Wickesberget al., 1994; Hirsch et al., 1999).

We have previously shown that denervated afferent pathways undergo rapid changes in strength. For example, evoked inhibitorypostsynaptic responses in the lateral superior olivary nucleus(LSO) become smaller within 24 hr of deafferentation (Kotak andSanes, 1996). Furthermore, this decrease is accompanied by a 8mV depolarization in the IPSP reversal potential, suggesting thatchloride homeostasis might be affected. Inhibitory disuse alsoresults in heterosynaptic affects. Thus, when the contralateralinhibitory input is disrupted, the unmanipulated excitatory pathwaybecomes stronger, apparently because of the addition of functionalNMDA receptors (Kotak and Sanes, 1996). Changes in the strengthof inhibitory afferents have also been suggested by in vivo studiesof deafness and presbycusis (Kitzes and Semple, 1985; Milbrandtet al., 1994; Bledsoe et al., 1995; Caspary et al., 1995; McAlpineet al., 1997; Milbrandt et al., 1997).

These studies raise interesting questions about the functional status of synapses in higher regions of the CNS. Therefore,we examined the inferior colliculus where the role of synapticinhibition in auditory processing has been most broadly studied(Park and Pollak 1993a,b, 1994; Le Beau et al., 1996; Sanes etal., 1998). The present study asked whether the disruption ofall spontaneous activity generated in the cochlea before the onsetof sound-driven activity commenced would influence the functionaldevelopment of two different inhibitory pathways through the laterallemniscus (LL) and the commissure of the inferior colliculus(CIC).

Parts of these results were published previously in abstract form (Vale and Sanes, 1999).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cochlear ablation. All protocols were reviewed and approved by the New York University Institutional Animal Care and Use Committee.Cochlear ablations were performed as described previously (Saneset al., 1992). Gerbil (Meriones unguiculatus) pups at postnatalday 7 (P7) were anesthetized with hypothermia until respirationceased and animals did not respond to nociceptive stimuli. A smallhole was made in the cochlear wall, and the contents were rapidlyremoved with a forceps. A piece of Gelfoam was placed in the cavity,and the wound was closed. Ablations were performed bilaterally.After surgery, animals were warmed on a heating pad and returnedto the litter when respiration and motor activity recovered. Bilaterallyablated animals were fed with a sterile saline solution containing0.1% glucose at 2-3 d after surgery. Successful ablations wereconfirmed before each brain sliceexperiment.

Brain slice preparation. Control and bilaterally ablated P8-P14 gerbils were anesthetized with chloral hydrate (350 mg/kg).After decapitation, the brain was blocked at the level of thethalamus and the caudal hindbrain. The ventral surface of thebrain was affixed to an agar block (cyanoacrylate glue), and theblock was secured to the stage of a vibratome (Leica, Nussloch,Germany). The tissue was cut in cold oxygenated artificial CSF(ACSF) containing (in mM): 123 NaCl, 4 KCl, 1.2 KH₂PO₄, 1.3 MgSO₄,28 NaHCO₃, 15 glucose, 2.4 CaCl₂, and 0.4 L-ascorbic acid, pH7.3 when oxygenated with 95%O₂/5%CO₂. Slices of 300 µm were obtainedin cold ACSF and maintained in an incubation chamber at room temperaturefor 2 hr. Slices containing the rostral inferior colliculus (IC)were placed in a recording chamber and superfused with oxygenatedACSF (7 ml/min) at roomtemperature.

Electrophysiology. Whole-cell voltage-clamp recordings (Warner Instruments PC-501A) were obtained as described previously(Kotak et al., 1998; Moore et al., 1998). Recording electrodeswere fabricated from borosilicate glass microcapillaries (1.5mm outer diameter), and the tip resistance was 5-10 M $Omega$ . For whole-cellvoltage-clamp recordings, the internal pipette solution contained(in mM): 127.5 cesium gluconate, 0.6 EGTA, 10 HEPES, 2 MgCl₂,5 KCl, 2 ATP, 0.3 GTP, and 5 QX-314 (Alamone, Jerusalem, Israel),pH 7.2. A measured liquid junction potential of ~5 mV was notcorrected, because our primary objective was to compare measuresbetween control and deafferented neurons. This error should affectboth values equally. Biocytin (~0.2%) was also added to the recordingsolution. Extracellular stimuli (200 µsec pulses) were deliveredthrough paired Teflon-insulated platinum electrodes driven byisolated biphasic stimulators (Intronics Instruments). Custompersonal computer-based software was used for programmed stimulusdelivery, data acquisition, and analysis (Sanes, 1993). Stimulatingelectrodes were placed in the afferent pathways from the CIC andthe LL. The maximum amplitude of evoked synaptic currents wastypically obtained at membrane holding potentials (E_hold) of $-$ 80and $-$ 20 mV. IPSC duration was determined from the rising latencyto the time at which the signal returned to the baseline noiselevel. The holding potential at which IPSCs reversed (E_IPSC) wasalso measured. At the end of each recording, slices were fixedin 4% paraformaldehyde, and a subset were processed to visualizebiocytin-filled neurons using an avidin-biotin complex coupledto horseradish peroxidase (Vector Laboratories, Burlingame,CA).

Passive membrane properties were evaluated using whole-cell current-clamp recordings (Warner Instruments PC-501A) in the presenceof kynurenic acid. The internal pipette solution contained (inmM): 135 potassium gluconate, 2 MgCl₂, 5 KCl, 0.6 EGTA, 10 HEPES,2 MgCl₂, 2 ATP, and 0.3 GTP, pH 7.2. The neuron input resistancewas calculated from the slope of current-voltage plots. Time constantswere determined as the time to reach 67% of the plateau amplitudeafter 0.1 nA hyperpolarizing currentpulses.

Many recordings (n = 86) were performed using the perforated patch technique (Rhee et al., 1994; Kyrozis and Reichling, 1995).Gramicidin (Sigma, St. Louis, MO) was used as the membrane-perforatingagent to permit the recording of IPSCs without influencing thecytoplasmic chloride concentration. Gramicidin was dissolved indimethylsulfoxide (DMSO; 2-5 mg/ml) and then diluted in the pipettesolution to a final concentration of 2-5 µg/ml (0.2% DMSO). Inour preparation, a further increase in gramicidin concentrationsled to rapid perforation and membrane rupture during the recordings.Gramicidin concentrations used in this study were lower than thoseused in some preparations (Kazaku et al., 1999) but close to thoseused for recordings from immature neurons of the cortex or auditorybrainstem (Owens et al., 1996; Backus et al., 1998). For perforatedpatch recordings, KCl was used in the pipette solution to preservethe function of potassium chloride cotransporters. With this solution,the measured liquid junction potential was ~4 mV, and the measurementswere uncorrected, because our primary objective was to comparemeasures between control and deafferented neurons. QX-314 wasretained in the intracellular pipette solution to confirm thatthe membrane did not rupture. The presence of depolarization-evokedbreakaway action potentials was taken as indication of the integrityof the gramicidin perforation. The progress of perforation wasevaluated by monitoring the decrease in membrane resistance. Afterthe membrane resistance had stabilized (between 5 and 40 min afterobtaining the G $Omega$ seal), data wereobtained.

Ionotropic glutamate receptors were blocked by adding a broad-spectrum ionotropic glutamate receptor antagonist, 5 mM kynurenicacid (Fluka Chemical, Ronkonkoma, NY) to the ACSF. The total IPSCwas blocked by the sequential addition of 2 µM strychnine (Sigma),a glycine receptor antagonist, and 10 µM bicuculline methobromide(Research Biochemicals, Natick, MA), a GABA_A receptor antagonist,to the ACSF. During the course of these experiments, we discovereda subpopulation of GABA_A receptors that were less sensitive tobicuculline, and this antagonist was used at higher concentrationsin some experiments, asindicated.

A one-way ANOVA followed by pairwise comparisons (Student's t test) was used to assess whether significant differences existedbetween neurons from control and bilaterally ablated animals,except as noted in Results. All values are expressed as mean ±SEM, with the number of observations in parentheses. The E_IPSCwas calculated from linear fits of the current-voltage curvesplotting IPSC amplitude versus membrane holding potential. Inhibitorysynaptic conductance was calculated as the slope of these samecurrent-voltagecurves.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Of the total number of IC neurons recorded in whole-cell voltage-clamp mode from control and experimental animals (n = 49),27 were recovered histologically and were assigned to locationsin the rostrocaudal plane and the central or lateral position.Fourteen cells were located in central positions, and the remainingstained cells were located either in lateral positions in theIC or in the border between the central and external cortex ofthe IC. Centrally located neurons within the IC generally exhibitedthe largest postsynaptic currents. All recorded IC neurons displayeda synaptic response to independent stimulation of the CIC andthe LL afferent pathways. Before the addition of kynurenic acid,LL- and CIC-evoked compound PSCs were typically inward at E_hold= $-$ 80 and outward or mixed at E_hold = $-$ 20 (Fig. 1).

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Figure 1. LL- and CIC-evoked synaptic currents from control and deafferented (BCA) neurons. Recordings were performed in whole-cell voltage clamp with cesium gluconate in the internal pipette solution. A, LL-evoked total PSCs are inward at $-$ 80 mV and outward at $-$ 20 mV for the control neuron. In BCA neurons, the total PSC tended to be inward at both $-$ 80 and $-$ 20 mV. In the presence of KYN the amplitude of the LL-evoked total IPSC was smaller in the BCA neuron (right) both at $-$ 20 and at $-$ 80 mV. With the addition of SN, LL-evoked GABAergic IPSCs were also smaller in the BCA neuron (right). After the addition of BIC, a measurable LL-evoked IPSC was still present in the control neuron but was absent in the BCA neuron. B, CIC-evoked PSCs were inward at $-$ 80 mV and outward at $-$ 20 mV for the control neuron. In the BCA neuron, the total PSC was inward at both $-$ 80 and $-$ 20 mV. In the presence of KYN, the amplitude of the CIC-evoked total IPSC was smaller in the BCA neuron (right) at $-$ 20 mV but similar to the control neuron at $-$ 80 mV. With the addition of SN, the CIC-evoked GABAergic IPSC was smaller in the BCA neuron (right) at $-$ 20 mV but similar to the control neuron at $-$ 80 mV. After the addition of BIC, a measurable CIC-evoked IPSC remained in the control neuron but was absent in the BCA neuron. The control neuron was from a P10 animal, and the BCA neuron was from a P11 animal.

Synaptic physiology in control neurons

The LL-evoked PSC amplitudes are shown for control neurons in Table 1 and Figure 1A. At E_hold = $-$ 80, the application of kynurenicacid (KYN) reduced LL-evoked inward synaptic currents by >60%but did not affect PSC amplitude at E_hold = $-$ 20 (Table 1). Thesynaptic current that remained in the presence of KYN (total IPSC)was composed of glycinergic and GABAergic components. The additionof 2 µM strychnine (SN) decreased the IPSC by 35-40%, and theaddition of 10 µM bicuculline (BIC) led to a further reductionin amplitude (Table 1, Fig. 1A). However, a significant synapticcurrent (>20 pA) remained in 7 of 17 control IC neurons, evenin the presence of all three antagonists. Three of these neuronswere tested with 5 µM SN, but this did not decrease the remainingcurrent. In four of these neurons, increasing BIC to 20-50 µMled to the elimination of the remaining currents.


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Table 1. LL-evoked postsynaptic current amplitude in control and BCA animals

Given the apparent differential sensitivity of IC neurons to bicuculline, a set of dose-response experiments were performedwith BIC. Figure 2A shows the response of increasing BIC concentrationson the amplitude of the postsynaptic GABAergic current in oneIC neuron (in the presence of KYN and SN). The inhibition producedby 10 µM BIC varied from 50 to 100% among the individual IC neurons(Fig. 2B). In all cases, the remaining currents in the presenceof KYN, SN, and 10 µM BIC were completely abolished by increasingthe concentration of BIC to 50 µM.

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Figure 2. Sensitivity of LL-evoked GABAergic IPSCs to bicuculline in control neurons. A, LL-evoked GABAergic IPSCs were obtained in the presence of 5 mM KYN and 2 µM SN at a holding potential of 0 mV. The BIC concentration is indicated on each trace. In this P14 neuron, there was a remaining IPSC at 20 µM BIC, but 50 µM eliminated the response. B, Bicuculline dose-response curves are shown for nine IC neurons. The LL-evoked response was expressed as a percentage of GABAergic IPSC recorded in the presence of KYN and SN only. The traces in A are represented by squares. The IPSC reduction produced by 10 µM BIC varied among the different neurons from 40 to 100%. In all neurons, the remaining IPSC was completely eliminated in the presence of 50 µM BIC.

Bilateral deafferentation: passive membrane properties

Bilateral cochlear ablation (BCA) did not produce a large change in the passive membrane properties of IC neurons. Membraneinput resistance was not significantly altered in BCA neurons(control, 311 ± 28 M $Omega$ ; n = 15; BCA, 268 ± 45 M $Omega$ ; n = 16). However,BCA caused a small, but significant, decrease in the membranetime constant from 30 ± 2 msec (n = 15) in control to 22 ± 2 msec(n = 16) in BCA neurons (df = 29; t = $-$ 2.388; p = 0.02). A decreasein the membrane time constant suggests that synaptic responsesshould be faster in BCA neurons. However, LL-evoked IPSCs fromcontrol neurons actually exhibited a slightly larger rising slopecompared with BCA neurons (control, $-$ 55 ± 9 pA/msec; BCA, $-$ 32± 5 pA/msec; df = 43; t = 2.112; p = 0.04). Therefore, passivemembrane properties of BCA neurons were not expected to influenceour measures of synaptictransmission.

Bilateral deafferentation: whole-cell voltage-clamp recordings

The following experiments document the size of evoked synaptic currents under different pharmacological conditions. The goalwas to isolate the inhibitory component (IPSCs) in control andBCA neurons. The IPSCs were analyzed at an E_hold of $-$ 20 and $-$ 80mV because the E_IPSC was generally in between these two potentials.The changes that we observed were similar for LL- and CIC-evokedsynaptic currents. Therefore, the results are presented togetherin this section, and all results are summarized in Tables 1 and2.


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Table 2. CIC-evoked postsynaptic current amplitude in control and BCA animals

Whole-cell voltage-clamp recordings were obtained with cesium gluconate in the internal pipette solution. Figure 1 shows examplesof afferent-evoked synaptic currents in control and BCA neuronsunder each pharmacological condition. Although there was a significantdecrease in the maximum amplitude of the LL-evoked mixed PSCs(Table 1, Fig. 1A), we do not believe that these effects canbe interpreted easily. Therefore, our analyses focused on pharmacologicallyisolated synapticinhibition.

The amplitudes of LL-evoked total IPSCs were significantly decreased, both at E_hold = $-$ 20 and $-$ 80 mV (Fig. 1A, Table 1).The maximum amplitude of LL-evoked IPSCs was ~70% smaller at $-$ 80mV (df = 43; t = 2.76; p = 0.008) and ~80% smaller at $-$ 20 mV (df= 41; t = $-$ 3.63; p = 0.0008). Furthermore, IPSC duration was alsodecreased significantly after ablation (df = 43; t = $-$ 3.81; p= 0.0004). For example, at a holding potential of $-$ 80 mV, controlIPSCs had a maximum duration of 125 ± 12 msec (n = 25), and thisdeclined to 61 ± 11 msec (n = 20) in BCAneurons.

The amplitude of CIC-evoked postsynaptic currents in control and BCA neurons under each pharmacological condition is shownin Figure 1B and Table 2. Interestingly, BCA neurons only displayedsmaller IPSCs at E_hold = $-$ 20 mV (df = 44; t = $-$ 2.82; p = 0.007).At this holding potential, the maximum CIC-evoked total IPSCswere ~80% smaller than those of control neurons (Fig. 1B, Table2). Although the mean total IPSC amplitude was 40% below controlsat E_hold = $-$ 80, this value did not reachsignificance.

The dissimilar findings at each holding potential could be explained if E_IPSC shifted toward $-$ 20 mV in BCA neurons. That is,the reduced IPSC amplitude at a holding potential of $-$ 20 mV maybe attributable to reduced activity of GABA or glycine receptors,decreased presynaptic transmitter release, and a decreased drivingforce. In contrast, the IPSC amplitude recorded at a holding potentialof $-$ 80 mV was not reduced, because an increase in chloride drivingforce could compensate for decreased receptor function or transmitterrelease.

In fact, BCA neurons exhibited a significant depolarizing shift in the total IPSC reversal potential (df = 41; t = 2.9; p= 0.005). The E_IPSC of control neurons was $-$ 40 ± 3 (n = 23) versus $-$ 26 ± 4 (n = 20) mV in BCA neurons. A similar finding was observedfor LL-evoked IPSCs (data not shown). Figure 3 shows examplesof E_IPSC measured in one control and one BCA neuron. Because thedriving force (E_hold $-$ E_IPSC) influences IPSC amplitude, the inhibitoryconductance was calculated from the slope of the IPSC current-voltagecurves. For CIC-evoked currents, there was a significant decreasein the conductance of the total IPSC (df = 36; t = $-$ 2.66; p =0.011) in BCA neurons (Fig. 4). The conductance for LL-evokedtotal IPSC was also significatively decreased in ablated animals(df = 36; t = $-$ 3.32; p = 0.002).

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Figure 3. Effect of deafferentation on IPSC reversal potential assessed with whole-cell voltage-clamp recordings using cesium gluconate in the internal pipette solution. A, CIC-evoked IPSCs are shown for a P10 control neuron (left) and a P11 BCA neuron (right). B, The current-voltage relationship for inhibitory currents shown in A. The plot for the BCA neuron was unusually steep even though BCA conductance was smaller on average (see Results for details). The E_IPSC was approximately $-$ 45 mV in the control neuron (black line) and $-$ 30 mV in the BCA neuron (gray line).

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Figure 4. Conductance of LL- and CIC-evoked total and GABAergic IPSCs in control (gray bars) and BCA (open bars) neurons. Data are from whole-cell voltage-clamp recordings. Total inhibitory currents were obtained in the presence of KYN, and GABAergic synaptic currents were obtained in the presence of KYN and SN. Values are means ± SEM (n). *p < 0.05; **p < 0.01; ***p < 0.005 versus control neurons under the same condition.

To determine whether the changes in evoked-IPSCs were attributable to changes in GABAergic afferents, neurons were bathedin 5 mM KYN plus 2 µM SN. Table 1 shows that LL-evoked GABAergicIPSCs were smaller in BCA neurons compared with controls. Table2 shows that CIC-evoked IPSCs were smaller at a holding potentialof $-$ 20 but not $-$ 80 mV. Again, this was probably because of the15 mV depolarization of the GABAergic E_IPSC (control, $-$ 44 ± 3mV; n = 18; BCA, $-$ 29 ± 6 mV; n = 14; df = 30; t = 2.383; p = 0.0237).As shown in Figure 4, the calculated conductance for CIC-evokedGABAergic IPSCs was ~50% smaller in BCA neurons (df = 27; t = $-$ 2.40; p = 0.023). A similar observation was made for LL-evokedGABAergic IPSCs (Fig. 4).

In control IC neurons, a significant component of the IPSC remained in the presence of all three antagonists (5 mM KYN, 2µM SN, and 10 µM BIC). This was found for both LL- and CIC-evokedIPSCs (Tables 1, 2). However, this remaining current was absentin BCA neurons at all holding potentials. Therefore, the GABAergiccomponent that was less sensitive to BIC in control neurons (Fig.2) was apparently absent afterdeafferentation.

Gramicidin-perforated patch recordings

Because our initial results with whole-cell recordings showed that the IPSC equilibrium potential was regulated by ablation,we repeated the experiments using gramicidin-perforated patchrecordings in which chloride ions do not pass through the perforation.Furthermore, we used normal potassium in the pipette so as notto perturb potassium chloride cotransporter mechanisms (Kazakuet al., 1999). In perforated patch recordings, the resting membranepotential of control and BCA neurons was $-$ 55 ± 1 mV (n = 45) and $-$ 58 ± 1 mV (n = 33),respectively.

Figure 5A shows LL-evoked IPSCs obtained at a series of holding potentials for individual control and BCA neurons. The current-voltagerelationship was linear in both cases (Fig. 5B). As shown in Figure6A, the E_IPSC measured in the presence of KYN was depolarizedby 24 mV after deafferentation (control, $-$ 74 ± 2 mV; n = 45; BCA, $-$ 50 ± 2 mV; n = 33; df = 76; t = 8.537; p < 0.0001). The intracellularCl concentration ([Cl^-]_i) was calculated by the Nernst equation, assuming: E_Cl= E_IPSP = RT/Fln([Cl]_o/[Cl]_i). Given an extracellular free Cl concentration ([Cl]_o) of 133.8 mM, and T = 293 K (20°C), the estimated [Cl]_i was elevated from 8 ± 1 mM (n = 45) in control neurons to 22± 3 mM (n = 33) in BCA neurons. This calculation assumes thatthe ligand-coupled channels are exclusively permeable to Cl. As shown in Figure 6B, the effect of deafferentation on E_IPSCwas rapid. The regression lines through the plot indicate thatthe control and experimental groups diverged within 1 d of themanipulation. Multiple ANOVA of these data indicated a significanteffect of both age (F = 5.12; p = 0.026) and experimental condition(F = 73.96; p < 0.0001). Also shown in Figure 6B are the resultsof recordings from control P7 neurons, the age of the bilateralablations, which showed that E_IPSC was $-$ 55 ± 5 mV (n = 8).

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Figure 5. Effect of deafferentation on IPSC reversal potential assessed with gramicidin-perforated patch recordings and potassium chloride in the internal pipette solution. A, LL-evoked IPSCs are shown for a P10 control neuron (left) and a P8 BCA neuron (right). B, Current-voltage relationship for inhibitory currents shown in A. The E_IPSC was approximately $-$ 65 mV in the control neuron (black line) and $-$ 40 mV in the BCA neuron (gray line).

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Figure 6. IPSC reversal potential in gramicidin-perforated patch recordings with KCl in the internal pipette solution. A, BCA caused a 24 mV depolarization in the mean E_IPSC (***p < 0.0001 vs control). B, The distribution of E_IPSC is plotted for neurons from control (black circles) and bilaterally ablated (gray squares) animals, along with regression lines. The effect of deafferentation on E_IPSC was apparent within 1 d of the surgical manipulation at P7 and persisted during the age range studied (up to P14). The E_IPSC of control neurons at P7 is shown at the left (see Results for statistics).

Because the effect of BCA was very rapid (Fig. 6B), an additional set of control experiments were performed to determine whetherthe short period of surgical anoxia could account for the findings.P7 animals were anesthetized with hypothermia until respirationstopped, but no surgery was performed. Recordings were then madeat P10-P11 to determine the possible influence of anoxia. TheE_IPSC for neurons from anesthetized animals was $-$ 68 ± 3 mV (n= 6), and this value was not significantly different from neuronsfrom nonanesthetized age-matched controls (df = 26; t = 1.769;p > 0.05).

Paired pulse facilitation in control and deafferented neurons

The presynaptic release characteristics were evaluated by delivering paired stimulus pulses and measuring the relative amplitudeof the second IPSC. Two pulses of equal strength were deliveredat interpulse intervals of 200, 100, 50, and 33 msec. This analysiswas performed with stimuli that elicited a minimum IPSC amplitude(presumed to reflect the evoked response of one or a few inhibitoryterminals). As shown in Figure 7A, control neurons showed an increasein the amplitude of the second LL-evoked IPSC compared with thefirst at all interpulse intervals tested, and this facilitationwas small or absent in BCA neurons. Figure 7B shows the mean valuesfor each pulse interval. Significant differences between controland BCA neurons were observed at stimulus intervals of 10 (df= 29; t = $-$ 2.11; p < 0.043), 20 (df = 29; t = $-$ 3.81; p < 0.001),and 30 Hz (df = 27; t = $-$ 2.93; p = 0.007). Results were similarfor paired pulses delivered to the CIC pathway (data not shown).

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Figure 7. Analysis of paired pulse facilitation. A, Stimuli that evoked the minimum IPSC amplitude were delivered to the LL pathway at frequencies of 5, 10, 20, and 30 Hz in a control (left) and a BCA (right) neuron. The amplitude of the second IPSC was larger at all the stimulus intervals for the control neuron (left) but was unchanged in the BCA neuron (right). The holding potential was $-$ 80 mV (thus, synaptic currents are somewhat smaller for the control neuron, because E_IPSC was $-$ 45 mV, whereas E_IPSC was $-$ 10 mV for the BCA neuron). B, Summary of the effect of paired pulse stimulation in neurons from control (black circles) and BCA (gray circles) animals. Data were obtained after electrical stimulation of the LL pathway in the presence of 5 mM KYN. Data from whole-cell and gramicidin-perforated recordings were pooled; n = 14 for BCA and 17 for control. *p < 0.05; ***p < 0.0001, ANOVA followed by t test.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The major finding of this study was that deafferentation influenced the development of inhibitory synapses in IC neurons viaa postsynaptic alteration of the chloride equilibrium potentialand a change in presynaptic release mechanisms. The bilateralcochlea ablations were performed at P7, ~4 d before the onsetof sound-driven activity, and the synaptic effects were observedwithin 24 hr. Cell death can be detected in the gerbil cochlearnucleus at 2 d after ablation (Hashisaki and Rubel, 1989), althoughthe process is not yet complete. Therefore, we suggest that changesin synaptic transmission were elicited by both the loss of spontaneoussynaptic activity and the physical loss of afferents. In fact,spontaneous discharges have been recorded in the gerbil IC fromP9 to P13 (Kotak and Sanes, 1995). Moreover, spontaneous activityin the IC is much lower in acutely ablated animals (Bock and Webster,1974; Shepherd et al., 1999). The effects were similar, but notidentical, for inhibitory afferents of the LL and CIC pathways.Although this could be attributable to the differential loss ofafferents in the two pathways that is secondary to denervation,there is currently no information on this point. Deafferentationdid not alter resting membrane potential or input resistance.There was a small, but significant, decrease in the membrane timeconstant, suggesting that BCA neurons may have atrophied, resultingin a smaller membrane capacitance. Because the slope of LL-evokedIPSC was actually faster in BCA neurons (see Results), the passivemembrane properties did not apparently affect our measures ofsynaptictransmission.

Inhibitory synaptic currents in control IC neurons

Both CIC and the LL provide strong inhibitory and excitatory input to gerbil IC neurons, and such mixed input can be dissectedpharmacologically in a brain slice preparation (Smith, 1992; Wagner,1996; Lo et al., 1998; Moore et al., 1998). Because total PSCsare a result of complex interactions between excitatory and inhibitorycomponents (Moore et al., 1998), we chose not to calculate the"excitatory" component by substracting total IPSCs from the compoundPSCs. Therefore, the present study leaves open the question ofwhether there is BCA-induced modification of LL- and CIC-evokedexcitatory synaptic currents. Furthermore, although much is knownabout the anatomy of ascending inhibitory projections to the IC,the present findings do not identify how each afferent sourceis affected by the manipulation (Adams, 1979; Nordeen et al.,1983; Coleman and Clerici, 1987; Shneiderman et al., 1988, 1993;Saint Marie and Baker, 1990; Saldaña and Merchan, 1992; Malmiercaet al., 1995; Winer et al., 1995; González-Hernández et al., 1996;Merchan et al., 1997; Oliver et al., 1997; Saint Marie et al.,1997).

All neurons displayed LL- and CIC-evoked IPSCs (Fig. 1; Tables 1, 2), similar to our published results (Moore et al., 1998),with the exception that the recorded currents were somewhat largerin the present study. This may be attributed to the location ofrecording. In this study, recording sites were restricted to themost central region of the IC at a rostrocaudal level that includedthe largest number of lemniscal fibers entering the ventral IC.Our experience is that neurons in this location tend to have thelargest evoked inhibitory currents. Both LL- and CIC-evoked IPSCshad comparable GABAergic and glycinergic components. Moore etal. (1998) showed that the LL pathway provided GABAergic and glycinergicinput to IC neurons, as expected from the diverse innervationthat IC neurons receive from auditory brainstem nuclei (SaintMarie and Baker, 1990; Shneiderman et al., 1993; González-Hernándezet al., 1996; Saint Marie et al., 1997). It is possible that theSN-sensitive component of CIC-evoked IPSCs was an artifact, becauseimmunocytochemical studies indicate that inhibitory CIC projectionsare GABAergic (González-Hernández et al., 1996), and glycinergicneurons are absent in adult IC (Winer et al., 1995). The closeproximity of the CIC stimulating electrode to the border of ICcould have directly activated glycinergic terminals within theIC. However, direct stimulation of terminals attributable to currentspread would have produced a negligible latency between stimulusartifact and IPSC onset, and this was not observed (Fig. 1B).A more plausible explanation is the coexistence of both GABA-and glycine-mediated inhibition in immature CIC afferents. Forexample, inhibitory afferents in the developing LSO co-releaseGABA and glycine, but the GABAergic component declines with age(Kotak et al., 1998).

Control neurons also displayed a differential sensitivity to bicuculline (Fig. 2). Similar results have been reported previouslyin developing tissue (Liu et al., 1998). This observation suggeststhat GABA_A receptor subunit expression in the developing IC mayproduce heteromeric receptors with different pharmacological characteristics(Laurie et al., 1992; Fritschy et al., 1994).

Inhibitory synaptic strength decreases after deafferentation

Bilateral cochlear ablation at P7 caused a significant decrease in the amplitude of evoked inhibitory synaptic currents inthe IC (Fig. 1; Tables 1, 2). This effect was more pronouncedin the LL pathway compared with the CIC pathway, possibly becauseof a decrease in the number of presynaptic afferents from lowerbrainstem nuclei. A decrease in the number of inhibitory LL afferentswould be expected, because partial or complete cochlear dysfunctionduring early postnatal development can produce rapid cell deathin the cochlear nucleus (Parks, 1979; Hashisaki and Rubel, 1989).It is not known whether there is compensatory sprouting afterbilateral ablation, as occurs in unilaterally ablated animals(Moore and Kitzes, 1985; Kitzes et al., 1995; Russell and Moore,1995).

Whether or not afferents were lost after deafferentation, this study demonstrated that the physiology of remaining inhibitoryafferents was altered significantly. In particular, the reversalpotential of evoked IPSCs was depolarized. Our initial whole-cellrecordings showed a 14 mV depolarization for total IPSCs and forthe pure GABAergic IPSCs (Fig. 3). However, even control neuronsdisplayed IPSC reversal potentials that were positive to thatpredicted by the intracellular and extracellular Cl concentrations. One factor that may lead to a depolarized E_IPSCis the presence of cesium in the recording pipette, which maycause a reversal of the potassium chloride cotransporter (Kazakuet al., 1999). Therefore, an extensive set of recordings was madein control and ablated animals using gramicidin-perforated patchrecordings (Rhee et al., 1994; Kyrozis and Reichling, 1995; Owenset al., 1996) with potassium chloride in the pipettesolution.

In perforated patch recordings, the mean E_IPSC from BCA neurons was depolarized by 24 mV. Furthermore, this effect was presentwithin 1 d of bilateral ablation (Figs. 5, 6). A similar observationwas made previously in the LSO, although the data were obtainedwith whole-cell recordings in current clamp (Kotak and Sanes,1996). A depolarization of E_IPSC would be expected to alter theIPSC driving force, and this would affect the IPSC amplitude recordedat different holding potentials. Thus, our failure to see significantchanges on the CIC-evoked total and GABAergic IPSCs and LL-evokedGABAergic IPSCs at $-$ 80 mV is attributable to the fact that thedepolarization of E_IPSC increased the driving force when BCA neuronswere held at $-$ 80 mV, enhancing the evoked IPSCamplitude.

The mechanisms responsible for E_IPSC depolarization are not yet understood; a growing body of literature indicates that thecomplement of chloride transporter proteins may underlie the depolarizingGABA- and glycine-evoked responses in immature neurons (Payneet al., 1996; Plotkin et al., 1997; Backus et al., 1998; Kazakuet al., 1999; Rivera et al., 1999; Williams et al., 1999). Furthermore,anoxia has been shown to depolarize the reversal potential ofGABAergic IPSCs in the hippocampus (Katchman et al., 1994). Thus,we would speculate that the intracellular chloride accumulationinduced by deafferentation is caused by an alteration of chlorideextrusion mechanisms, such as the K⁺/Cl cotransporter. Alternatively, the Na⁺/K⁺/Cl (NKCC) cotransporter, which pumps chloride into the postsynapticcell, may be overactive. It has been found that NMDA receptoractivation can stimulate an NKCC cotransporter (Sun and Murali,1998). Whether BCA causes GABAergic and glycinergic transmissionto become excitatory (e.g., to evoke action potentials) remainsto bedetermined.

There was also a large reduction of inhibitory strength that was apparently independent of driving force. The conductanceof evoked IPSCs was reduced by ~50%, and this was found for boththe LL and CIC afferents (Fig. 4). This could have occurred asa result of loss of inhibitory afferents, reduction in the amountof GABA or glycine release, reduction of postsynaptic GABA orglycine receptors, or an alteration in the functional status ofthese receptors. In fact, we observed that deafferentation resultedin the apparent loss of a class of GABA_A receptors that are lesssensitive to BIC. In control neurons, there was often an evokedIPSC that remained in the presence of KYN, SN, and 10 µM BIC.However, this remaining IPSC was not observed in BCA neurons (Tables1, 2). This may indicate an alteration in the expression ofGABA_A receptor subunits, as shown in presbycusis (Milbrandt etal., 1997).

We also found that the inhibitory transmission is disrupted at presynaptic terminals after deafferentation. A paired stimulusprotocol was used to evaluate the function of inhibitory terminalsin control and BCA neurons (Fig. 7). Control neurons displayedan increase in the synaptic response to the second stimulus pulseat rates of 10, 20, and 30 Hz, and this potentiation was virtuallyabsent in BCA neurons. This observation indicates that neurotransmitterproduction and/or release from the presynaptic terminal is disruptedby deafferentation. A decrease in GABA release in the inferiorcolliculus has been reported after BCA (Bledsoe et al., 1995)and in hippocampal neurons from animals treated with kainate orpilocarpine (Hirsch et al., 1999). There is also a decrease ofGABA and glycine release in several nuclei with projections toIC after partial deafferentation (Suneja et al., 1998a).

Compensatory sprouting of afferent projections after the removal of one cochlea leads to novel projections in the gerbil superiorolive and inferior colliculus (Moore and Kitzes, 1985; Kitzeset al., 1995; Russell and Moore, 1995). These changes extend toa molecular level. Sensory deprivation results in alterationsof transmitter release (Bledsoe et al., 1995; Potashner et al.,1997; Suneja et al., 1998a) and changes in the distribution ofexcitatory and inhibitory receptors (Suneja et al., 1997, 1998b;Koch and Sanes, 1998). In vivo electrophysiological studies confirmthat these structural alterations produce novel sound-evoked codingproperties (Kitzes and Semple, 1985; Bledsoe et al., 1995). Thepresent results indicate that normal innervation, before sound-drivenactivity, regulates inhibitory transmission in IC neurons. Short-termdeafferentation led to a decrease in LL- and CIC-evoked IPSC amplitude,partially because of a postsynaptic alteration in chloride equilibriumpotential. In addition, deafferentation caused a decrease in thefunctionality of single inhibitory synaptic terminals. Therefore,alterations in auditory processing after deafness may be causedby physiological changes of inhibitory synaptictransmission.

  FOOTNOTES

Received July 19, 1999; revised Dec. 7, 1999; accepted Dec. 20, 1999.

This work was supported by National Institutes of Health GrantDC00540.
Correspondence should be addressed to Dan H. Sanes, Center for Neural Science, 4 Washington Place, New York University, NewYork, NY 10003. E-mail: sanes{at}cns.nyu.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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