Depolarization Selectively Increases the Expression of the Kv3.1 Potassium Channel in Developing Inferior Colliculus Neurons

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (35)

Citing Articles via Google Scholar

Google Scholar

Articles by Liu, S.-q. J.

Articles by Kaczmarek, L. K.

Search for Related Content

PubMed

PubMed Citation

Articles by Liu, S.-q. J.

Articles by Kaczmarek, L. K.

Previous Article  |  Next Article

The Journal of Neuroscience, November 1, 1998, 18(21):8758-8769

Depolarization Selectively Increases the Expression of the Kv3.1 Potassium Channel in Developing Inferior Colliculus Neurons
Si-qiong J. Liu and Leonard K. Kaczmarek
Department of Pharmacology, Yale University School of Medicine, New Haven, Connecticut 06520-8066

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The Kv3.1 channel subunit, when expressed heterologously, gives rise to a high-threshold noninactivating potassium current.Experiments with auditory neurons have suggested that the presenceof this channel subunit enables them to fire action potentialsat high frequencies. We have found that the expression levelsof Kv3.1 transcripts increase in inferior colliculus neurons beforethe onset of hearing and then remain relatively constant. Becausespontaneous neuronal activity plays an important role in modulatingneuronal excitability during development, we examined the effectsof depolarization with an elevated concentration of external potassiumions on the expression of Kv3.1 channel subunits in immature inferiorcolliculus neurons. Elevated potassium produced a marked increasein Kv3.1 mRNA levels and in the amplitude of a high-threshold,noninactivating current before the onset of hearing. This increasewas prevented by the presence of a calcium channel blocker, indicatingthat calcium influx mediated the depolarization-induced increasein this current. In contrast, treatment with an elevated externalpotassium concentration caused only a moderate increase in thepeak amplitude of a lower-threshold inactivating current. Therepolarization of action potentials in the high-potassium-treatedcells was more rapid and complete than in the control cells. Computersimulations confirmed that this change could be explained by achange in Kv3.1-like current of the same magnitude as recordedin voltage-clamp experiments. Thus, depolarization and calciuminflux may alter the excitability of immature inferior colliculusneurons by selectively increasing the levels of a Kv3.1-like potassiumcurrent.

Key words: potassium channel; expression; depolarization; inferior colliculus; Kv3.1; calcium

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Neuronal activity plays an important role in the development of the CNS. Both spontaneously generated and experience-dependentneuronal activity are essential for the functional and structuralmaturation of connections in the visual system (Katz and Shatz,1996). The intrinsic membrane properties of neurons also undergodynamic changes during development. One of the mechanisms underlyingsuch changes is the regulation of the levels of potassium channels.Whether neuronal activity regulates the expression of potassiumchannels during development, however, remains largely unknown.

One potassium channel subunit that regulates the excitability of rapidly firing neurons is the Shaw-type channel, Kv3.1. TheKv3.1 gene gives rise to two transcripts: Kv3.1a and Kv3.1b (Luneauet al., 1991). Although the Kv3.1a and Kv3.1b proteins differat the C terminus, they both produce high-threshold noninactivatingdelayed-rectifier currents when expressed heterologously (Yokoyamaet al., 1989; Kanemasa et al., 1995). Kv3.1 mRNA and protein areexpressed in a subpopulation of neurons in brain (Perney et al.,1992; Weiser et al., 1995). Some of the neurons that contain theKv3.1 protein have also been demonstrated to possess a high-threshold,noninactivating Kv3.1-like current and are capable of firing actionpotentials at a rapid rate (Brew and Forsythe, 1995; Du et al.,1996; Massengill et al., 1997; Wang et al., 1998). Experimentalevidence and computer simulations suggest that repolarizationof action potentials by Kv3.1-like currents minimizes the relativerefractory period, enabling these neurons to fire at increasedfrequencies (Massengill et al., 1997; Perney and Kaczmarek, 1997).Moreover, pharmacological elimination of the high-threshold Kv3.1-likecurrent in auditory neurons specifically reduces their abilityto follow high-frequency stimulation (Wang et al., 1998).

The inferior colliculus is a major relay center along auditory pathways (Morest and Oliver, 1983; Oliver and Shneiderman,1991) and is developmentally plastic (Feldman et al., 1996). Studiesof the tonotopic organization of the inferior colliculus havesuggested that the ability of the colliculus to respond to highersound frequency inputs occurs later in development than the responseto lower frequencies and that this may be related to the maturationof the cochlea (Ehret and Romand, 1994; Pierson and Snyder-Keller,1994). However, maturation of the intrinsic excitability of inferiorcolliculus neurons may also contribute to the developmental changesin this region. Because all the neurons in the inferior colliculusexpress Kv3.1 mRNA and protein (Perney et al., 1992; Weiser etal., 1994), one possible mechanism underlying developmental changesin this region is an increase in the expression level of Kv3.1.

Depolarization with external potassium ions increases the levels of Kv3.1 mRNA in AtT20 cells and upregulates the activityof the Kv3.1 promoter (Perney and Kaczmarek, 1993; Gan et al.,1996). However, whether depolarization affects the expressionof the Kv3.1 potassium channel in auditory neurons during developmentis not yet known. As in the visual system, spontaneous activityhas been observed in the auditory system before the onset of hearing(Kotak and Sanes, 1995). In the present study we have investigatedwhether depolarization by potassium ions regulates the expressionof Kv3.1 in inferior colliculus neurons during maturation andwhether it influences the firing properties of these neurons.

  MATERIALS AND METHODS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation and incubation of slices of inferior colliculus. Inferior colliculi were obtained from decapitated 3- to 30-d-oldSprague-Dawley rats and placed in standard artificial CSF (ACSF)containing (in mM): 125 NaCl, 2.5 KCl, 26 NaHCO₃, 1.25 NaH₂PO₄,2 CaCl₂, 1 MgCl₂, 10 glucose, pH 7.4, which was bubbled continuouslywith a 95% O₂ and 5% CO₂ mixture. The inferior colliculus wascut into slices (300-500 µm) in ice-cold ACSF solution, and theslices were then incubated in ACSF, in high-K ACSF (77.5 mM NaCland 50 mM KCl with the other components unchanged), or in high-KACSF containing 1 mM Cd²⁺ and 2 mM EGTA at room temperature for 6 hr. In experiments usingisolated neurons of the inferior colliculus, we found that elevationof the external potassium ion concentration to 50 mM depolarizedthe cells from their resting potential to approximately $-$ 29 mV,a value close to the predicted equilibrium potential for potassiumions. For convenience we shall refer to the incubation of inferiorcolliculus slices in high-K ACSF as "depolarization."

Deoxyglucose uptake assay. We tested the viability of inferior colliculus slices incubated in ACSF by measuring their uptakeof 2-deoxy-[1-³H]-glucose ([³H]DG) (Amersham, Arlington Heights, IL), as described previously(Liu and Kaczmarek, 1998). Briefly, inferior colliculi were dissectedfrom rats, cut into halves, and then weighed and sliced. Halfof the slices were incubated with [³H]DG in ACSF at 0°C, and the other half were incubated at roomtemperature, both for 40 min. The slices were then washed threetimes in ice-cold ACSF and homogenized in 1% SDS. The levels of[³H]DG were then measured by liquid scintillation counting. Theratio of [³H]DG uptake at room temperature relative to that at 0°C (R_DG)was used to evaluate the viability of slices (see Table 1). Ina separate series of experiments, slices were incubated in oxygenatedACSF for 6 hr at room temperature, before the [³H]DG uptake assay. R_DG values from these slices were not significantlydifferent from those without subsequent incubation in ACSF (seeTable 1), indicating that inferior colliculus slices from postnatalrats remain viable for a period of 6 hr in ACSF.

RNase protection assay. RNA was isolated from inferior colliculus slices immediately after each rat was killed (t = 0) orafter 6 hr incubation in ACSF or in high-K ACSF. Total RNA wasisolated from each sample by the guanidinium thiocyanate acidphenol-chloroform method (Chomcyznski and Sacchi, 1987), and RNAconcentrations were measured using a spectrophotometer. PlasmidDNA containing the coding region of the Kv3.1b gene subclonedinto pGEM-A (Luneau et al., 1991) was digested with PvuII. [³²P]CTP-labeled antisense RNA probe was transcribed with SP6 polymerase,using the linearized plasmid as the DNA template. This probe (413base pairs) is complementary to the 108 bases of the 3' end ofKv3.1a and to the 398 bases of Kv3.1b mRNA (Perney et al., 1992)and was used to measure the levels of the Kv3.1a and Kv3.1b transcripts.Linearized pTRI-GAPDH-rat (Ambion) was used as a DNA templateto generate an antisense mRNA (434 base pairs) that hybridizedwith a 316 base fragment of the glyceraldehyde 3-phosphate dehydrogenase(GAPDH) RNA (a housekeeping enzyme). The levels of GAPDH mRNAwere measured and used as an internal control. The RNase protectionassay was performed using published procedures (Ausubel et al.,1990). Total RNA (5 µg) isolated from inferior colliculus of postnatalday 3 (P3), P8, P15, or P33-40 was hybridized with [³²P]CTP-labeled antisense RNA probes. The amount of probe used inthis experiment was in molar excess of the RNA in samples of allages, because when 10 µg of total RNA was hybridized with thesame amount of antisense RNA probes, higher densitometric intensityvalues of the Kv3.1- and GAPDH-protected bands were obtained ateach age (data not shown).

The amount of radioactivity in each band was visualized by autoradiography and was quantified on a densitometer by integratingthe area under the peak. In a previous study, we determined thatthe range of densitometric readings that were linearly proportionalto the radioactivity of the bands is between 500 and 7000 U (Liuand Kaczmarek, 1998). Therefore, in each experiment the gel wasexposed to x-ray film for varying lengths of time. Only when thedensitometric intensity values of the Kv3.1- and GAPDH-protectedbands were within the linear range were the data used for furtheranalysis. The relative levels of Kv3.1a and Kv3.1b mRNA were calculatedby dividing the intensity of the Kv3.1a or Kv3.1b band by theintensity of the GAPDH band. In addition to the protected bandscorresponding to Kv3.1a [108 nucleotide (nt)], Kv3.1b (434 nt),and GAPDH (316 nt), several other bands were also present. Thesebands have been seen when GAPDH probe was not used (Perney etal., 1992), and the intensities of these bands did not vary inproportion to the intensity of bands corresponding to Kv3.1 bmRNA (Liu and Kaczmarek, 1998). Thus these protected bands couldnot be the degradation products of GAPDH or Kv3.1b mRNA and shouldnot affect the measurement of Kv3.1a and Kv3.1b mRNA levels.

Isolation of inferior colliculus neurons from slices. After incubation in ACSF, high-K ACSF, or high-K ACSF containing 1 mMCd, inferior colliculus slices were incubated in oxygenated ACSFcontaining 0.4 mg/ml collegenase A1 (Sigma, St. Louis, MO) for1 hr and then in 10 mg/ml papain (Sigma) at room temperature for30 min. The slices were washed with ACSF and maintained in ACSFbubbled continuously with 95% O₂ and 5% CO₂ until used. Each ofthese slices was transferred to extracellular solution containing(in mM): 150 NaCl, 5 KCl, 1 MgCl₂, 2 CaCl₂, 10 mM glucose, 10HEPES, pH 7.4, in a 35 mm dish (Corning, Corning, NY), mechanicallyseparated using a pair of microelectrodes, and then trituratedthrough glass pipettes.

Electrophysiological recordings. Whole-cell patch-clamp recordings were made at room temperature (20-24°C) from acutely isolatedinferior colliculus neurons in the extracellular solution (asspecified above), using an Axopatch-1D amplifier. The patch pipetteswere pulled from thin-walled borosilicate glass (WPI, Gaithersburg,MD) with a resistance of 4-10 M $Omega$ when filled with intracellularsolution. The intracellular solution contained (in mM): 70 KCl,70 potassium gluconate, 1 CaCl₂, 11 EGTA, 10 HEPES, 5 MgCl₂, 2.5Mg-ATP, pH 7.4. After breakthrough into the whole-cell mode, theresting membrane potential was measured. To determine whetherthe cell was a neuron, the response to test pulses delivered between $-$ 20 and 30 pA in current-clamp mode were recorded. Only the cellsthat fired action potentials were used for the voltage-clamp recordings.Series resistances (11.4 ± 0.8 M $Omega$ ; mean ± SEM, n = 28) were compensatedto 80%. Cell capacitance (19.4 ± 0.8 pF) was measured from thetransient currents produced by a 10 mV voltage step and directlyfrom the amplifier after compensation for series resistance. Thecells were then voltage-clamped at $-$ 70 mV, and test pulses weredelivered from $-$ 80 to 60 mV, with a 1 sec prepulse to $-$ 100 or $-$ 30 mV. Leak currents were monitored throughout the experiment,but not subtracted, unless stated otherwise. Current density wascalculated by dividing the current amplitude by the cell capacitance.All data are presented as the mean ± SEM.

Computer modeling. Modeling of the inferior colliculus neurons was performed using methods described previously for othercells (Kanemasa et al., 1995; Perney and Kaczmarek, 1997; Wanget al., 1998). The voltage-dependence and kinetic parameters ofthe high-threshold Kv3.1-like currents were simulated exactlyas described in detail by Wang et al. (1998) for Kv3.1 currentrecorded in transfected Chinese hamster ovary (CHO) cells. Conductances(g_K) were adjusted to match current levels recorded in the presentexperiments [g_K = 0.019 µS (see Fig. 11B); g_K = 0.01 µS (see Fig.11C); g_K = 0.022 µS (see Fig. 11D)]. The low-threshold potassiumcurrent I_lt and voltage-dependent inward currents I_in were simulatedby the equations I_lt = g_lt(E_K $-$ V) and I_in = g_inm³h (50 $-$ V).

The evolution of the variables q, l, m, and h was determined by Hodgin-Huxley-like equations as described in full by Perneyand Kaczmarek (1997). Activation parameters for the low-thresholdpotassium currents were k_l = 1.2 msec^1, $eta$ _l = 0.03512 mV^-1, k_l = 1.2 msec¹, and $eta$ _l = $-$ 0.03188 mV^-1. Inactivation parameters for the low-threshold current were k_q= 0.001 msec^1, $eta$ _q = $-$ 0.00543 mV^-1, k_q = 0.00175 msec¹, and $eta$ _q = 0.00956 mV^-1. Corresponding parameters for inward current were k_m = 76.4msec^1, $eta$ _m = 0.037 mV^-1, k_m = 0.0027 msec¹, $eta$ _m = $-$ 0.003 mV^-1, k_h = 0.000593 µsec^1, $eta$ _h = $-$ 0.227 mV^-1, k_h= 1.065 msec¹, and $eta$ _h= 0.013 mV^-1. Numerical simulations of the responses of cells to externalstimulation were performed using the equation C dV/dt = I_K + I_lt+ I_in + g_L(E_L $-$ V) + Iext(t), where g_L represents a leakage conductanceand where external currents Iext(t) were presented as step currents.For all simulations E_L = $-$ 60 mV, C = 0.005 nF, and g_L= 0.005 µS.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Changes in the levels of Kv3.1a and Kv3.1b mRNA during development

We measured the levels of Kv3.1a and Kv3.1b mRNA in the inferior colliculus at P3, P8, P15, and P33 using an RNase protectionassay. The expression levels of both Kv3.1a and Kv3.1b mRNA increaseduring development (Fig. 1). Kv3.1a mRNA was the dominant transcriptthroughout development. The levels of Kv3.1a mRNA were approximatelyeightfold and threefold higher than the levels of Kv3.1b mRNAat P3 and P33, respectively (Fig. 1A). A pronounced increase inthe expression levels of Kv3.1 transcripts occurred between P3and P8. Relative to the levels of Kv3.1 transcripts at P3, therewas a 2.1-fold increase in Kv3.1b and a 1.4-fold increase in Kv3.1aat P8 (Fig. 1B). In contrast, there was relatively little changein the levels of the Kv3.1a and Kv3.1b transcripts after P8.

View larger version (14K):
[in this window]
[in a new window]
Figure 1. Expression levels of Kv3.1a and Kv3.1b mRNA during development. A, The intensities of the Kv3.1a band determined by densitometric measurements were multiplied by 3.6 to account for the differences in the number of labeled C residues in the protected bands of Kv3.1a and Kv3.1b, as described previously (Perney et al., 1992). The levels of the Kv3.1a and Kv3.1b mRNA are normalized by the total amount of GAPDH mRNA. Each point is the mean of two measurements from one experiment. B, Normalized expression levels of Kv3.1a and Kv3.1b mRNA. The Kv3.1a and Kv3.1b mRNA levels determined from the average of two or three measurements for each RNA preparation at each developmental stage were divided by the mean values for these mRNAs at P3 determined in the same experiment. Data are mean ± SEM. n values (numbers of independent RNA preparations) at P3, P8, P18, and P30 are 3, 3, 2, and 2, respectively. The changes in the Kv3.1b mRNA levels are significantly different by ANOVA testing among these age groups, with p < 0.01. A Tukey-Kramer multiple-comparisons test showed that the change in the Kv3.1b mRNA expression at P30 was significantly different from that at P3 and P8, with p < 0.01 and 0.05, respectively.

Regulation of Kv3.1 transcripts by depolarization

To investigate the possible role of neuronal activity in the developmental regulation of Kv3.1 mRNA levels, we examined theeffects of depolarization on the expression of Kv3.1a and Kv3.1bmRNAs during development, using an in vitro slice preparation.We first tested the viability of inferior colliculus slices inACSF by measuring the uptake of 2-deoxyglucose and found thatinferior colliculus slices remained viable in ACSF for at least6 hr at all ages tested (Table 1). We also examined whether invitro incubation by itself altered the levels of Kv3.1 expressionand found that the ratio of mRNA levels after incubation in ACSFfor 6 hr to that of control was 1.00 ± 0.09 (n = 18) for Kv3.1aand 1.08 ± 0.07 (n = 26) for Kv3.1b. Thus, incubation in ACSFfor 6 hr did not change the levels of Kv3.1a and Kv3.1b mRNA.


View this table:
[in this window]
[in a new window]
Table 1. Effect of incubation in ACSF on the deoxyglucose uptake

In the following experiments, inferior colliculus slices from animals at P3, P8, and P15 were incubated in ACSF or in high-KACSF for 6 hr at room temperature. The levels of Kv3.1a and Kv3.1bmRNA were subsequently determined using an RNase protection assay.Depolarization with high-K ACSF induced a marked increase in thelevels of Kv3.1b transcripts at P3 and P8 (Fig. 2A,B). Interestinglythe depolarization did not affect the expression levels of Kv3.1transcripts at P15, a developmental period when there was relativelylittle change in the levels of Kv3.1. Thus the depolarization-inducedincrease in Kv3.1 mRNA levels appears to correlate temporallywith the changes in the levels of Kv3.1 transcripts during development.

View larger version (29K):
[in this window]
[in a new window]
Figure 2. Modulation of Kv3.1 mRNA levels by depolarization during development. A, Effects of high-K treatment on the levels of the Kv3.1a and Kv3.1b mRNA, detected by an RNase protection assay, at P3 and P15. RNA was isolated from inferior colliculus slices incubated in ACSF and in high-K ACSF for 6 hr at room temperature. The bands corresponding to the Kv3.1b, Kv3.1a, and GAPDH mRNAs are 398, 108, and 316 nucleotides, respectively. B, Summary of the effects of depolarization onKv3.1a and Kv3.1b mRNA levels at P3, P8, and P15. Because there was variability in the specific activity of the GAPDH probe between experiments, the changes in the Kv3.1a and Kv3.1b mRNA levels were determined within each experiment. We calculated the average values of relative levels of Kv3.1a and Kv3.1b mRNA in the ACSF control sample and the changes in the Kv3.1a and Kv3.1b mRNA levels as follows:

All values are mean ± SEM. n values (the number of independent RNA preparations) at P3, P8, and P15 are 3, 4, and 2, respectively. The changes in Kv3.1b mRNA levels at P3 and P8 are significantly different from 0, p < 0.05 and p < 0.01, respectively, by a two-tailed Student's t test.

We also examined whether the neurotrophins BDNF and NT-3 and the growth factors FGF and NGF affected the expression of Kv3.1transcripts in the inferior colliculus slices at P3, P8, P15,and P30-40. Treatment with these factors in ACSF for 6 hr didnot significantly alter the levels of Kv3.1a and Kv3.1b mRNA (datanot shown).

Isolation of a Kv3.1-like potassium current in inferior colliculus neurons

Inferior colliculus neurons are known to express several potassium channels, including Kv3.1 (Beckh and Pongs, 1990; Perneyet al., 1992; Weiser et al., 1994). To investigate the possibleeffects of depolarization on currents conducted by the Kv3.1 channelin inferior colliculus neurons, we isolated a potassium currentthat has the characteristics of the Kv3.1 channel, i.e., a high-threshold,noninactivating current that is sensitive to TEA (Yokoyama etal., 1989; Luneau et al., 1991; Kanemasa et al., 1995).

Acutely dissociated neurons from inferior colliculus were voltage-clamped and held at $-$ 70 mV. A family of total outward currents(I_pp-100) evoked by a series of voltage steps to potentials between $-$ 80 and 60 mV, after a 1 sec prepulse to $-$ 100 mV, is illustratedin Figure 3A. Voltage-dependent outward currents were activatedat potentials to $-$ 40 mV (Fig. 3D) and contained an inactivatingcomponent and a noninactivating component. In contrast, aftera prepulse to $-$ 30 mV for 1 sec, outward currents (I_pp-30) wereactivated only at potentials positive to $-$ 20 mV in these cells(Fig. 3D). The latter currents did not undergo inactivation duringdepolarization lasting 1600 msec (Fig. 3B). Thus, a transientoutward current with a low activation threshold could be eliminatedby the 1 sec prepulse to $-$ 30 mV. Subtracting the noninactivatingcurrent after the $-$ 30 mV prepulse from the total current gaverise to a family of currents that represent this transient component(Fig. 3C).

View larger version (30K):
[in this window]
[in a new window]
Figure 3. Different components of the outward current in voltage-clamped inferior colliculus neurons. Cells were held at $-$ 70 mV and stepped to a prepulse potential of $-$ 100 mV (A) or $-$ 30 mV for 1 sec (B), before the voltage was stepped to potentials between $-$ 80 and 60 mV (D), or between $-$ 70 and 50 mV (A, B) in 20 mV increments. A, Total current after a 1 sec prepulse to $-$ 100 mV. B, Outward current after a 1 sec prepulse to $-$ 30 mV. C, The difference current obtained by subtracting current in B from the current in A. D, Voltage dependence of the peak amplitude of total currents after a prepulse to $-$ 100 mM ( $triangle$ ) and of the steady-state current after a prepulse to $-$ 30 mM ( $black-square$ ).

We varied the voltage of the prepulse from $-$ 100 to $-$ 30 mV (Fig. 4A). The peak current amplitude decreased as the potentialof the prepulse was made more positive and appeared to level offat approximately $-$ 50 mV. We also changed the duration of the prepulseat $-$ 30 mV and found that a prepulse of 0.5 sec was sufficientto suppress most of the inactivating current (Fig. 4B). A longerprepulse did not further reduce the current amplitude. We thereforeused 1 sec prepulses to $-$ 30 and $-$ 100 mV in our experiments tomeasure the noninactivating current and the total currents, respectively.These prepulses did not alter the kinetics and amplitude of Kv3.1currents in CHO cells transfected with the Kv3.1 gene (data notshown).

View larger version (13K):
[in this window]
[in a new window]
Figure 4. Effects of prepulse potential and prepulse duration on the peak current amplitude at 0, 20, and 40 mV. A, Measurements of peak current amplitude after prepulse potentials between $-$ 100 and $-$ 30 mV for 1 sec. B, Measurements of current amplitude after a prepulse to $-$ 30 mV for duration between 0 and 5 sec.

The current generated by the Kv3.1 channel subunit, when expressed in cell lines, is strongly inhibited by 1-2 mM TEA (Kanemasaet al., 1995). We therefore examined the effects of 2 mM TEA onthe currents evoked after a $-$ 30 mV prepulse and found that TEAreversibly eliminated these currents (Fig. 5A,B) (n = 3). Thiscurrent was also inhibited by 100 µM 4-AP (n = 2; data not shown).The characteristics of these high-threshold currents thereforegenerally resemble those of Kv3.1 in their high activation threshold,lack of inactivation, and sensitivity to TEA and 4-AP.

View larger version (17K):
[in this window]
[in a new window]
Figure 5. TEA inhibits the high-threshold current, whereas Cd²⁺ does not affect this current. Currents of acutely dissociated inferior colliculus neurons were recorded in response to voltage steps from $-$ 80 to +60 mV in 20 mV increments after a prepulse to $-$ 30 mV for 1 sec. An extracellular solution containing 2 mM TEA (A, B) or 0.5 mM Cd²⁺ (D) was perfused into the recording dish, and cells were then washed with extracellular solution. A, Bath application of 2 mM TEA inhibited the high-threshold current. The inhibition was reversed by perfusing extracellular solution without TEA. The last three data points were measured in the presence of 1 µM TTX. B, Current traces before TEA (1), in the presence of 2 mM TEA (2), and after washing (3). The currents were leak-subtracted and filtered at 500 Hz. C, D, Current traces of an inferior colliculus neuron before (C) and during (D) application of 0.5 mM Cd²⁺.

Because we identified neurons among all dissociated cells in a dish by their ability to fire action potentials in responseto injection of depolarizing currents, we did not include TTXin the extracellular solution in most of the experiments. In severalexperiments, however, we superperfused extracellular solutioncontaining 1 µM TTX into the bath solution to determine whetherthe sodium current alters the amplitude of the steady-state currentafter the $-$ 30 mV prepulse. TTX did not change the amplitude ofthe high-threshold steady-state outward current (data not shown;n = 3). We also tested whether calcium current or calcium-activatedpotassium current contributes to the high-threshold, noninactivatingcurrents by measuring the total current before and after the superperfusionof extracellular solution containing 0.5 mM Cd²⁺. Cd²⁺ did not alter the amplitude of this current (Fig. 5C,D) (n =3).

Depolarization increases the current density of the high-threshold, noninactivating current

We next examined whether the increase in the Kv3.1 mRNA induced by depolarization results in an increase in the current densityof the high-threshold, noninactivating current in inferior colliculusneurons. Inferior colliculus slices obtained from P3-P6 rats wereincubated in high-K ACSF or in ACSF for 6 hr, and then treatedwith collagenase and papain in ACSF. Cells were then mechanicallydissociated from the slices in extracellular solution. First,the properties of the cells were determined in the current-clampmode to distinguish neurons from glia. For each neuron, we measuredthe capacitance of the cell, resting membrane potential, and inputresistance. The resting membrane potentials of high-K-treatedcells (mean ± SEM = $-$ 63 ± 4 mV, n = 9; values ranged from $-$ 50to $-$ 80 mV) were not significantly different from those of controlcells ( $-$ 59 ± 3 mV, n = 17; ranging from $-$ 30 to $-$ 74 mV). The inputresistance of high-K-treated cells was 323 ± 72 M $Omega$ (n = 11) andthat of control cells was 320 ± 46 M $Omega$ (n = 17).

We then measured the outward currents in these inferior colliculus neurons in response to voltage steps between $-$ 80 and 60mV after a 1 sec prepulse to $-$ 30 mV. Current traces from a controlinferior colliculus neuron at P5 and those from a high-K-treatedP5 neuron are shown in Figure 6A. An averaged value of currentdensity is plotted against command potential in Figure 6B. Inboth control and high-K-treated cells, currents were activatedat potentials positive to $-$ 20 mV and showed no inactivation. However,the high-K-treated cells had a 2.2-fold higher current densitythan that of controls. The changes in current density producedby previous depolarization appear to quantitatively agree withthe changes in the Kv3.1 mRNA levels (Fig. 2B).

View larger version (23K):
[in this window]
[in a new window]
Figure 6. High-K depolarization induces an increase in the current density of the high-threshold current. A, Typical examples of high-threshold current recorded from control cells (left) and high-K-treated cells (right). B, Current density versus voltage curves were generated for both control (n = 19) and high-K-treated cells (n = 10). Data points are mean ± SEM. The current density in high-K-treated cells is significantly different from that of control at $-$ 10 mV (p < 0.01) and from 0-60 mV (p < 0.001) (two-tailed Student's t test).

Because the levels of Kv3.1 mRNA increased between P3 and P8, we examined whether the density of this high-threshold, noninactivatingcurrent also increases over this period in the dissociated inferiorcolliculus neuron. The amplitude of the current density at 20mV increased from 74 ± 9 pA/pF (n = 5) at P3 to 125 ± 10 pA/pF(n = 3) at P6 in the control cells (p < 0.01) (Fig. 7). This increaseappeared to be consistent with the increase in the levels of Kv3.1mRNA during this developmental period (Fig. 1). The high-K-treatedcells consistently had a higher current density than that of controlcells of the same age (Fig. 7). This correlates with our observationthat depolarization increases the levels of Kv3.1 mRNA at bothP3 and P8.

View larger version (12K):
[in this window]
[in a new window]
Figure 7. Developmental changes in current density of the high-threshold current at +20 mV after a prepulse to $-$ 30 mV for 1 sec in control ( $open circle$ ) and high-K-treated ( $bullet$ ) inferior colliculus neurons. The current density in control cells increases during development. High-K treatment induced an increase in the current density at each of the early postnatal days examined.

Ca²⁺ influx mediates the increase in the amplitude of high-threshold currents

An increase in intracellular calcium concentration of immature neurons plays an important role in the maturation of neuronalconnectivity and in developmental changes in the expression ofion channels (Gu and Spitzer, 1995; Wong et al., 1995). We thereforetested whether the high-K ACSF-induced increase in high-thresholdcurrent amplitude in the immature inferior colliculus neuronsrequires Ca²⁺ influx by blocking voltage-gated calcium currents with Cd²⁺. P4 inferior colliculus slices were incubated in high-K ACSFor in high-K ACSF containing 1 mM Cd²⁺ for 6 hr. Neurons were dissociated from the slices after thesetreatments. The current density after a prepulse to $-$ 30 mV inthe neurons incubated in high-K ACSF containing Cd²⁺ remained at the control level (Fig. 8). Thus this Ca²⁺ channel inhibitor blocked the depolarization-induced increasein amplitude of the high-threshold current, suggesting that theincrease in current is mediated by calcium influx during the depolarization.Because in the AtT20 cell line blocking L-type calcium channelsprevented the high-K-induced upregulation of Kv3.1 mRNA expression(T. M. Perney and L. K. Kaczmarek, unpublished data), we incubatedthe inferior colliculus slices in high-K ACSF in the presenceof 100 µM nifedipine, a blocker of L-type channel. Nifedipinecompletely blocked the depolarization-induced increase in currentdensity of the high-threshold current (the current density at+20 mV was 16.0 ± 0.6 pA/pF; n = 4), suggesting that the majorsource of calcium influx is through L-type channel.

View larger version (9K):
[in this window]
[in a new window]
Figure 8. The depolarization-induced increase in high-threshold current density requires calcium influx. Inferior colliculus slices from P4 rats were incubated in high-K, in high-K ACSF containing 1 mM Cd, or in ACSF for 6 hr at room temperature. The neurons were then acutely dissociated from the inferior colliculus slices. After a 1 sec prepulse to $-$ 30 mV, evoked currents were measured at +20 mV. Data are mean ± SEM. The current density of the high-K-treated sample (n = 5) is significantly different from that of control (n = 5) (p < 0.001) and from that of the high-K ACSF Cd²⁺ samples (n = 3) (p < 0.01), by a two-tailed Student's t test.

Effects of depolarization on the inactivating current

As described above, the outward currents in inferior colliculus neurons consist of inactivating currents and noninactivatingcurrents, and these components can be separated by applying prepulsesto $-$ 30 and $-$ 100 mV (Fig. 3). We therefore tested whether the depolarizationspecifically increases the current density of the high-threshold,noninactivating current or whether it also affects the inactivatingcurrents. Currents were measured after a prepulse to $-$ 100 mV,and the noninactivating current evoked after a prepulse to $-$ 30mV was subtracted from this current. The difference current activatedbetween $-$ 40 and $-$ 20 mV (Figs. 3C, 9). The averaged current densityfor the peak of this difference current was smaller than thatof the noninactivating current (Figs. 6B, 9). Treatment with elevatedpotassium caused only a moderate increase (47%) in the peak valueof the difference current. Thus depolarization appears preferentiallyto upregulate the expression of noninactivating current in earlypostnatal inferior colliculus neurons.

View larger version (18K):
[in this window]
[in a new window]
Figure 9. Effects of high-K depolarization on the inactivating current obtained by subtracting the current after a 1 sec prepulse to $-$ 30 mV from the total current after a 1 sec prepulse to $-$ 100 mV. Peak current density versus voltage curves were generated for both control (n = 17) and high-K-treated cells (n = 8). Data points are mean ± SEM. The mean current density in high-K-treated cells is different from that in control cells at $-$ 20, $-$ 10, 0, 10, 40, and 60 mV (p < 0.05) by a two-tailed Student's t test.

Depolarization alters the electrophysiological properties of inferior colliculus neurons

The kinetic properties of Kv3.1 current and the high-threshold current in inferior colliculus neurons, namely high-activationthreshold and lack of inactivation, indicate that these currentsshould facilitate rapid repolarization of action potentials. Totest the hypothesis that the selective upregulation of the high-thresholdcurrent affects the electrophysiological properties of inferiorcolliculus neurons during maturation, we examined the firing propertiesof control and of high-K-treated cells in normal extracellularsolution.

The majority of control inferior colliculus neurons (63%) and many high-K-treated cells (44%) fired only a single action potentialin response to sustained depolarizing current (10-20 pA, 160 msec),whereas the remainder were capable of generating two to five spikesin response to the same stimuli (Table 2). These results areconsistent with previous studies of the responses of inferiorcolliculus neurons in slices (Peruzzi and Oliver, 1994; Wisgirdaet al., 1996). Repolarization of the action potentials duringthe current pulse was associated with an afterhyperpolarization(AHP), after which the membrane potential decayed passively towardits steady-state value (Fig. 10). We measured three parametersof action potential repolarization: (1) the amplitude of the firstaction potential, (2) the latency from the peak of the actionpotential to the peak of the subsequent AHP, and (3) the differencein membrane potential between the peak AHP and the resting potential.The amplitude of the first action potential in control cells wasnot different from that in high-K-treated cells. The durationof the decay phase of the action potentials, however, was significantlyreduced in the high-K-treated cells (Table 2, Fig. 10). Moreover,the degree of repolarization was significantly enhanced in thehigh-K-treated cells, as measured by the differences between theAHP and resting potential. These data indicate that repolarizationin high-K-treated cells is more rapid and complete than in thecontrol cells.


View this table:
[in this window]
[in a new window]
Table 2. Effects of depolarization on electrophysiological properties of inferior colliculus neurons

View larger version (6K):
[in this window]
[in a new window]
Figure 10. Representative whole-cell voltage recordings from a control neuron (A) and from a high-K-treated neuron (B), isolated from P5 inferior colliculus. Action potentials were evoked by a 160 msec depolarizing current pulse of 10 pA. The rate of repolarization of action potential was 30.6 mV/msec in the control cell and 44.7 mV/msec in the high-K-treated cell. The difference between AHP and resting potential was 8.83 mV in the control and $-$ 0.5 mV in the high-K-treated cell.

To determine whether the increase in high-threshold current alone can account for the change in the action potential repolarization,we performed computer simulations of the isolated inferior colliculusneurons. We simulated a cell that has voltage-sensitive inwardcurrent, a leak conductance, and two components of K current:an inactivating conductance and a high-threshold noninactivatingconductance. The activation and deactivation parameters of thenoninactivating current matched those of Kv3.1 current recordedin CHO cells (Wang et al., 1998), and its conductance was adjustedto levels of current recorded in the inferior colliculus neurons(Fig. 11B). The inactivating current was fitted to an A-type currentmodel, and its conductance and kinetic parameters were adjustedto fit closely to the recorded difference currents (Fig. 11A).Inward current parameters were adjusted to give action potentialsthat matched those recorded in these experiments. Simulated actionpotentials were triggered by a 160 msec suprathreshold currentpulse (Fig. 11C). As the conductance of noninactivating K currentwas increased by 2.2-fold, the repolarization of the simulatedaction potentials and the magnitude of the AHP were enhanced ina manner that closely resembled voltage traces recorded from thehigh-K-treated inferior colliculus neurons (Fig. 10A,B). Thus anincrease in the density of a Kv3.1-like current alone, by thesame amount that occurs in response to depolarization by elevatedpotassium concentrations, can produce the more rapid and completerepolarization of action potentials measured in these experiments.

View larger version (10K):
[in this window]
[in a new window]
Figure 11. Computer simulations of the effects of a Kv3.1-like potassium conductance on action potential repolarization in inferior colliculus neurons. Inactivating (A) and noninactivating (B) potassium currents of the model cells were fit closely to the current traces shown in Figure 3B,C. C, D, Action potentials were simulated in response to 20 pA current pulses in model cells with varying levels of the high-threshold noninactivating current. The trace in D represents a 2.2-fold increase in the conductance of the noninactivating potassium current over that in C, with no changes in other parameters. The increase in this current enhanced the AHP.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The expression of potassium channels changes throughout development and plays an important role in determining the excitabilityof neurons (Ribera and Spitzer, 1992). In the present study wefound a marked increase in the levels of Kv3.1 mRNA in the inferiorcolliculus neurons from P3 to P8. We also identified a noninactivatinghigh-threshold, TEA-sensitive potassium current in the neuronsacutely isolated from the P3-P6 inferior colliculus. This currenthas all the characteristics expected of a Kv3.1-type current andundergoes a 1.7-fold increase in amplitude from P3 to P6. Thisis comparable to the increase in the levels of Kv3.1 mRNA in thedeveloping inferior colliculus neurons over the same time period.

Increases in the levels of Kv3.1a and Kv3.1b mRNA and Kv3.1b protein during development have also been found in cerebellum(Liu and Kaczmarek, 1998) and in hippocampal interneurons (Duet al., 1996). However, the temporal expression pattern of thesesplice variants in inferior colliculus cells differs from thatin cerebellum. The Kv3.1a transcript predominates in early postnataldays in cerebellum, whereas the levels of Kv3.1b mRNA increaseand exceed those of Kv3.1a mRNA during subsequent development.In contrast, Kv3.1a appears to be the dominant transcript in inferiorcolliculus throughout development. This difference in the temporalexpression pattern of splice variants suggests that there existscell type-specific regulation of the expression of the Kv3.1 potassiumchannel.

Upregulation of Kv3.1 expression by depolarization

Our observation that treatment with high-K ACSF induces an increase in the expression of Kv3.1 in developing inferior colliculusneurons is consistent with the earlier observation that depolarizationincreases Kv3.1 mRNA levels in AtT20 cells (Perney and Kaczmarek,1993). Depolarization has also been shown to alter the expressionof a Ca²⁺-activated potassium channel gene in cerebellum (Muller et al.,1998) and the Kv1.5 potassium channel in pituitary cells (Levitanet al., 1995) via calcium-dependent and calcium-independent pathways,respectively. In the present experiments, we found that blockingCa²⁺ channels with Cd²⁺ prevented the depolarization-induced increase in amplitude ofa high-threshold Kv3.1-like current. Thus the effect of depolarizationis likely to be mediated by an increase in Ca²⁺ influx. Because elevated potassium concentrations have been shownto enhance the activity of the Kv3.1 promoter, depolarizationmay elevate the levels of Kv3.1 expression in developing inferiorcolliculus neurons by increasing Kv3.1 promoter activity (Ganet al., 1996).

Effects of depolarization with high-K ACSF on the expression of Kv3.1 appears to depend on the cell type as well as its stageof development. In cerebellum at P8, depolarization alone doesnot affect the expression of Kv3.1, but selectively suppressesthe FGF-induced upregulation of Kv3.1a mRNA by inhibiting PKCactivation (Liu and Kaczmarek, 1998). Thus, different cellularmechanisms appear to regulate the expression of Kv3.1 mRNA indifferent cell types.

Functional role of the high-threshold current in developing inferior colliculus neurons

In the present study, we used prepulses of $-$ 100 and $-$ 30 mV to separate a noninactivating, high-threshold, and TEA-sensitivecurrent from other inactivating currents. A similar method hasbeen used to isolate currents that have all the characteristicsof Kv3.1-type current in neurons of the medial nucleus of thetrapezoid body and in cortical neurons (Brew and Forsythe, 1995;Massengill et al., 1997; Wang et al., 1998) in which Kv3.1 mRNAand protein are present (Perney et al., 1992; Weiser et al., 1994).In addition to the Kv3.1 channel, mRNA for another Shaw-subfamilypotassium channel, Kv3.3, is present in inferior colliculus neurons(Weiss et al., 1994). Kv3.3 current, like Kv3.1, activates atpotentials positive to $-$ 20 mV and is sensitive to TEA and 4-AP.These two channels differ, however, in their inactivation kinetics.The Kv3.3 gene, when expressed alone in oocytes, produces currentthat inactivates substantially in 100 msec, whereas Kv3.1 expressesa noninactivating, delayed rectifier-type current. Coassemblyof Kv3.1 and Kv3.3 subunits is likely to produce a current withintermediate inactivation kinetics, as has been shown for co-expressionof the Kv3.1 and Kv3.4 genes (Weiser et al., 1994). In our experiments,however, the currents measured after a $-$ 30 mV prepulse exhibitedno inactivation, and therefore most closely resemble the characteristicsof Kv3.1 expressed alone. Calcium currents, which could activatecalcium-dependent potassium currents during depolarization, havebeen characterized in inferior colliculus neurons and appear tobe of the L and N type (N'Gouemo and Rittenhouse, 1997). Becausethe presence of Cd²⁺, which blocks these channels, did not alter the amplitude ofthe steady-state outward current after a $-$ 30 mV prepulse, theactivation of calcium-dependent potassium currents appears tobe very small under our experimental conditions.

We have shown that depolarization induces an increase in the high-threshold, noninactivating currents and that this increasein current density parallels an increase in Kv3.1 mRNA levels.In contrast, depolarization caused only a moderate increase inthe inactivating component of potassium currents. Computer simulationstudies have demonstrated that an increase in Kv3.1-like currentallows cells to follow high rates of synaptic stimulation (Kanemasaet al., 1995; Perney and Kaczmarek, 1997; Wang et al., 1998).Consistent with this, higher levels of Kv3.1 mRNA and Kv3.1-likecurrent have been found in fast-spiking cortical neurons thanin regular-spiking cortical neurons (Massengill et al., 1997),and elimination of Kv3.1-like currents prevents auditory neuronsin the medial nucleus of the trapezoid body from following high-frequencystimuli (Wang et al., 1998). In inferior colliculus neurons, wehave shown that the repolarization of action potentials in thehigh-K-treated cells was more rapid and complete than in the controlcells. Although this produces only a minor change in the responseof the isolated cells to a sustained depolarizing current, enhancedrepolarization is likely to enhance the response of the cellsto repetitive synaptic stimulation (Perney and Kaczmarek, 1997;Wang et al., 1998). Furthermore, computer simulation of actionpotentials in inferior colliculus neurons indicated that an increasein Kv3.1-like current by itself was sufficient to produce suchchanges in repolarization. Thus selective upregulation of Kv3.1could enable these neurons to fire at high frequencies in responseto synaptic stimulation, with very little changes in the amplitudeof their action potentials.

Differential regulation of the expression of Kv3.1 by depolarization during development

We have demonstrated that depolarization with an elevated potassium concentration upregulates the expression of Kv3.1 in P3and P8 neurons but not in P15 neurons of the inferior colliculus.This suggests that depolarization affects expression only at earlydevelopmental stages, before the onset of hearing (P12-P14) (Kelly,1992). Interestingly, spontaneous neuronal activities are presentin many immature neurons and neural networks and contribute tothe refinement of neuronal connections within the visual systembefore the onset of vision (Wong et al., 1995; Shatz, 1996). Spontaneousactivity has been recorded in the nucleus magnocellularis andin the nucleus laminaris of the developing chick auditory system(Lippe, 1994) and in immature mammalian auditory neurons, includinginferior colliculus neurons (Kotak and Sanes, 1995). Althoughthe average rates of neuronal discharge in mammalian auditoryneurons appear to be low during development, low-frequency stimulationof an excitatory pathway from the cochlear nucleus induces a long-lastingdepolarization (up to 34 min) of neurons in the lateral superiorolive of early postnatal gerbils before the onset of hearing (Kotakand Sanes, 1995). Such a prolonged depolarization may increaseCa²⁺ influx and could regulate the transcription of ion channels andother proteins (Spitzer, 1991; Gu and Spitzer, 1995). In our experiments,incubation of inferior colliculus slices in high-K ACSF may exerteffects similar to those of spontaneous synaptic activity, whichbefore the onset of hearing may provide signals required for thematuration of intrinsic membrane properties. Our findings suggest,therefore, that Ca²⁺ influx plays a role in the maturation of potassium channel expressionin auditory neurons before the onset of hearing.

The failure of depolarization with a raised external potassium concentration to enhance expression of Kv3.1 in P15 neuronscould reflect developmental changes in intracellular signalingpathways. For example, depolarization inhibits PKC activity inP8 cerebellum but enhances PKC activity in the adult (Liu andKaczmarek, 1998). Alternatively, developmental changes in ionchannels (O'Dowd et al., 1988; Ribera and Spitzer, 1989) couldalter calcium dynamics in response to depolarization. Moreover,depolarization may cause release of neurotransmitters (Smith,1992), and the effects of elevated potassium ions could be mediatedby substances released during depolarization.

  FOOTNOTES

Received March 11, 1998; revised July 15, 1998; accepted Aug. 24, 1998.

This work was supported by Grant DC-01919 from National Institutes of Health (L.K.K.) and a National Research Service Awardfellowship (S.J.L.). We thank Drs. Neil Magoski, Lu-yang Wang,Matthew Whim, and Mary Wisgirda for helpful discussions and technicaladvice.
Correspondence should be addressed to Dr. Leonard K. Kaczmarek, Department of Pharmacology, Yale University School of Medicine,333 Cedar Street, New Haven, CT 06520-8066.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Ausubel FM, Brent R, Kingston RE, Moore DD, Seidmand JG, Smith JA, Struhl K (1990) In: Current protocols in molecular biology, pp 4.7.1-4.8.3. New York: Wiley.
Beckh S, Pongs O (1990) Members of the RCK potassium channel family are differentially expressed in the rat nervous system. EMBO J 9:777-782[ISI][Medline].
Brew HM, Forsythe ID (1995) Two voltage-dependent K⁺ conductances with complementary functions in postsynaptic integration at a central auditory synapse. J Neurosci 15:8011-8022[Abstract].
Chomcyznski P, Sacchi N (1987) Single-step method of RNA isolation by guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem 162:156-159[ISI][Medline].
Du J, Zhang L, Weiser M, Rudy B, McBain C (1996) Developmental expression and functional characterization of the potassium-channel subunit Kv3.1b in parvalbumin-containing interneurons of the rat hippocampus. J Neurosci 16:506-518[Abstract/Free Full Text].
Ehret G, Romand R (1994) Development of tonotopy in the inferior colliculus II: 2-DG measurements in the kitten. Eur J Neurosci 6:1589-1595[Medline].
Feldman DE, Brainard MS, Knudsen EI (1996) Newly learned auditory responses mediated by NMDA receptors in the owl inferior colliculus. Science 271:525-528[Abstract].
Gan L, Perney TM, Kaczmarek LK (1996) Cloning and characterization of the promoter for a potassium channel expressed in high frequency firing neurons. J Biol Chem 271:5859-5865[Abstract/Free Full Text].
Gu X, Spitzer NC (1995) Distinct aspects of neuronal differentiation encoded by frequency of spontaneous Ca²⁺ transients. Nature 375:784-787[Medline].
Kanemasa T, Gan L, Perney TM, Wang L-Y, Kaczmarek LK (1995) Electrophysiological and pharmacological characterization of a mammalian Shaw channel expressed in NIH 3T3 fibroblasts. J Neurophysiol 74:207-217[Abstract/Free Full Text].
Katz LC, Shatz CJ (1996) Synaptic activity and the construction of cortical circuits. Science 274:1133-1138[Abstract/Free Full Text].
Kelly JB (1992) Behavioral development of the auditory orientation response. In: Development of auditory and vestibular system 2 (Romand R, ed), pp 391-418. Amsterdam: Elsevier.
Kotak VC, Sanes DH (1995) Synaptically evoked prolonged depolarizations in the developing auditory system. J Neurophysiol 74:1611-1620[Abstract/Free Full Text].
Levitan ES, Gealy R, Trimmer JS, Takimoto K (1995) Membrane depolarization inhibits Kv1.5 voltage-gated K⁺ channel gene transcription and protein expression in pituitary cells. J Biol Chem 270:6036-6041[Abstract/Free Full Text].
Lippe WR (1994) Rhythmic spontaneous activity in the developing avian auditory system. J Neurosci 14:1486-1495[Abstract].
Liu SJ, Kaczmarek LK (1998) The expression of two splice variants of the Kv3.1 potassium channel gene is regulated by different signaling pathways. J Neurosci 18:2881-2890[Abstract/Free Full Text].
Luneau CJ, Williams JB, Marshall J, Levitan ES, Oliva C, Smith JS, Antanavage J, Folander K, Stein RB, Swanson R, Kaczmarek LK, Buhrow SA (1991) Alternative splicing contributes to K⁺ channel diversity in the mammalian central nervous system. Proc Natl Acad Sci USA 88:3932-3936[Abstract/Free Full Text].
Massengill JL, Smith MA, Son DI, O'Dowd DK (1997) Differential expression of K_4-AP currents and Kv3.1 potassium channel transcripts in cortical neurons that develop distinct firing phenotypes. J Neurosci 17:3136-3147[Abstract/Free Full Text].
Morest DK, Oliver DL (1983) The neuronal architecture of the inferior colliculus in the cat: defining the functional anatomy of the auditory midbrain. J Comp Neurol 222:209-236.
Muller YL, Reitstetter R, Yool AJ (1998) Regulation of Ca²⁺-dependent K⁺ channel expression in rat cerebellum during postnatal development. J Neurosci 18:16-25[Abstract/Free Full Text].
N'Gouemo P, Rittenhouse AR (1997) Pharmacological characterization of voltage-sensitive calcium currents in inferior colliculus neurons. Soc Neurosci Abstr 23:1187.
O'Dowd DK, Rebera AB, Spitzer NC (1988) Development of voltage-dependent calcium, sodium and potassium currents in Xenopus spinal neurons. J Neurosci 8:792-805[Abstract].
Oliver DL, Shneiderman A (1991) The anatomy of the inferior colliculus: a cellular basis for integration of monaural and binaural information. In: Neurobiology of hearing: the central auditory system (Altschuler RA, Bobbins RP, Clopton BM, Hoffman DW, eds), pp 195-222. New York: Raven.
Perney TM, Kaczmarek LK (1993) Expression and regulation of mammalian K channel genes. Semin Neurosci 5:135-145.
Perney TM, Kaczmarek LK (1997) Localization of a high threshold potassium channel in the rat cochlear nucleus. J Comp Neurol 386:178-202[ISI][Medline].
Perney TM, Marshall J, Martin KA, Hockfiels S, Kaczmarek LK (1992) Expression of the mRNAs for the Kv3.1 potassium channel gene in the adult and developing rat brain. J Neurophysiol 3:756-766.
Peruzzi D, Oliver DL (1994) Intracellular responses to current injection in slices of rat inferior colliculus (IC). Soc Neurosci Abstr 20:321.
Pierson M, Snyder-Keller A (1994) Development of frequency-selective domains in inferior colliculus of normal and neonatally noise-exposed rats. Brain Res 636:55-67[Medline].
Ribera AB, Spitzer NC (1989) A critical period of transcription required for differentiation of the action potential of spinal neurons. Neuron 2:1055-1062[ISI][Medline].
Ribera AB, Spitzer NC (1992) Developmental regulation of potassium channels and the impact on neuronal differentiation. In: Ion channels (Narahashi T, ed), pp 1-38. New York: Plenum.
Shatz CJ (1996) Emergence of order in visual system development. Proc Natl