Development of Intrinsic and Synaptic Properties in a Forebrain Nucleus Essential to Avian Song Learning

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Volume 17, Number 23, Issue of December 1, 1997

Development of Intrinsic and Synaptic Properties in a Forebrain Nucleus Essential to Avian Song Learning

Frederick S. Livingston and Richard Mooney
Department of Neurobiology, Duke University Medical Center, Durham, North Carolina 27710

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

In male zebra finches, the lateral magnocellular nucleus of the anterior neostriatum (LMAN) is necessary for the developmentof learned song but is not required for the production of acousticallystereotyped (crystallized) adult song. One hypothesis is thatthe physiological properties of LMAN neurons change over developmentand thus limit the ability of LMAN to affect song. To test thisidea, we used in vitro intracellular recordings to characterizethe intrinsic and synaptic properties of LMAN neurons in fledgling[posthatch days (PHD) 22-32] and juvenile zebra finches (PHD 40-51)when LMAN lesions disrupt normal song development, and in adults(>PHD 90) when LMAN lesions are without effect. In fledglings,depolarizing currents caused LMAN projection neurons to fire burstsof action potentials because of a putative low-threshold calciumspike (LTS). In contrast, juvenile and adult LMAN projection neuronsfired accommodating trains of action potentials when depolarizedbut did not exhibit the burst mode of firing. Electrical stimulationof thalamic afferents elicited both monosynaptic EPSPs mediatedby AMPA and NMDA receptors and polysynaptic IPSPs mediated byGABA_A receptors from LMAN neurons at all ages studied here. Inwhole-cell voltage-clamp recordings, the EPSCs (NMDA-EPSCs) consistedof fast and slow components. Unlike juvenile and adult NMDA-EPSCs,those in fledglings were dominated by the slower component. Thus,both the intrinsic and synaptic properties of LMAN neurons changemarkedly during early song development (PHD 22-40) and achieveseveral adult-like properties during early sensorimotor learningand well before the time when LMAN lesions no longer disrupt songdevelopment.
Key words: LMAN; DLM; song nuclei; zebra finch; whole cell; intracellular recordings; NMDA receptors; AMPA receptors; low-threshold calcium spike; LTS; vocal plasticity; critical periods; song learning

INTRODUCTION

The development and adult production of learned birdsong are controlled by a well defined CNS circuit known as the song system.Anterior forebrain nuclei, including the lateral magnocellularnucleus of the anterior neostriatum (LMAN), are essential to songdevelopment, but not to adult song production. As a first steptoward understanding the developmentally restricted role of theanterior forebrain loop, we have investigated changes in the electrophysiologicalproperties of LMAN neurons over the course of song learning.

Song learning begins with sensory acquisition, when the juvenile songbird first memorizes the song of another bird, and isfollowed by sensorimotor learning, when the bird matches its ownvocalization to the memorized song via auditory feedback (Konishi,1965; Price, 1979). Sensorimotor learning progresses from plasticsong, which has a highly variable acoustical structure, to crystallizedsong, which possesses a high degree of acoustical stereotypy (Immelmann,1969).

The production of learned song is controlled by serially linked forebrain structures that include nucleus HVc and the robustnucleus of the archistriatum (RA). RA neurons project both tothe tracheosyringeal portion of the hypoglossal nucleus (nXIIts),which innervates the muscles of the avian song organ (syrinx),and to expiratory nuclei, including the nucleus ambiguus and nucleusretroambigualis (nAm/nRam; see Fig. 1) (Nottebohm et al., 1976,1982; Wild, 1993). HVc and RA neurons exhibit increased activityduring singing (McCasland, 1987; Yu et al., 1996), and lesioningthese areas eliminates learned song while leaving unlearned vocalizationsintact (Nottebohm et al., 1976; Simpson and Vicario, 1990). HVcand RA also are connected indirectly by the anterior forebrainpathway (AFP), which includes area X, the medial nucleus of thedorsolateral thalamus (DLM), and LMAN (Okuhata and Saito, 1987;Bottjer et al., 1989). In zebra finches, LMAN lesions made atthe height of sensorimotor learning produce a sudden and prematureacoustical stereotypy that resembles crystallization (Bottjeret al., 1984; Scharff and Nottebohm, 1991), although similar lesionsmade in the adult zebra finch do not affect song production.
Fig. 1. The song system. A, Simplified schematic of the song system. The motor pathway (open structures) is essential for the productionof learned song and includes the nuclei HVc, RA, nAm/nRAm, andnXIIts. The anterior forebrain pathway (AFP; shaded structures)is critical for normal song development and contains X, DLM, andLMAN (D, dorsal; R, rostral). HVc, Used here as the proper name,also known as the higher vocal center; RA, robust nucleus of thearchistriatum; nAm, nucleus ambiguus; nRAm, nucleus retroambigualis;nXIIts, tracheosyringeal portion of the hypoglossal nucleus; X,area X of the lobus parolfactorius; DLM, medial nucleus of thedorsolateral thalamus; LMAN, lateral portion of the magnocellularnucleus of the anterior neostriatum. B, LMAN and area X in a transilluminatedparasagittal living brain slice, showing the ascending thalamicfibers from DLM (arrow). Scale bar, 800 µm.
[View Larger Version of this Image (52K GIF file)]

One hypothesis explaining the age-dependent effects of LMAN lesions is that LMAN neurons change physiologically during sensorimotorlearning, thus gradually altering the capacity of LMAN to influencesong quality. Two findings suggest that these changes involvesynaptic transmission within LMAN. Dendritic spine frequency ofLMAN projection neurons declines substantially between posthatchdays (PHD) 21-100 (Nixdorf-Bergweiler et al., 1995b), and NMDAreceptors within LMAN are downregulated over the same period (Aamodtet al., 1992; Basham, 1996). This latter finding, along with theobservation that the infusion of NMDA receptor antagonists intothe anterior neostriatum during sensory acquisition reduces thenumber of copied notes (Basham et al., 1996), suggests that thesesynaptic changes involve the NMDA receptor. Therefore, establishingwhether NMDA receptor-mediated synaptic currents in LMAN changeduring development is essential, especially because NMDA receptor-mediatedcurrents at other synapses change as sensitive periods close (Carmignotoand Vicini, 1992; Hestrin, 1992; Ramoa and McCormick, 1994; Crairand Malenka, 1995). Thus, we have characterized the intrinsicand synaptic properties of adult (>PHD 90) male zebra finch LMANneurons by using in vitro intracellular recordings and then havecompared these properties with those from younger birds at eitherthe beginning (PHD 22-32) or height (PHD 40-51) of sensorimotorlearning.

MATERIALS AND METHODS
Experiments were performed with brain slices made from male zebra finches in accordance with a protocol approved by the DukeUniversity Institutional Animal Care and Use Committee. Finchesused in these experiments ranged in age from 22-180 PHD and wereobtained from our breeding colony, which consisted of individuallycaged mating pairs and their offspring less than PHD 50 and groupholding cages that contained birds older than PHD 50. In thissetting, birds were not acoustically or visually isolated fromeach other. The three age groups used for these studies were betweenPHD 22-32, 40-51, and older than 90. These ages were chosen becausePHD 22-32 are at the onset of sensory acquisition in zebra finchesbut in large part predate the beginning of song production (Immelmann,1969; Arnold, 1975). Sonographic analysis indicates that, in ourcolony, birds between PHD 40-51 are in the early stages of sensorimotorlearning (and possibly still in the later phases of sensory acquisition;for review, see Slater et al., 1988). This middle age range isthe period when LMAN lesions also exert their most deleteriouseffects on song development (Bottjer et al., 1984). In contrast,birds greater than PHD 90 in our colony sing stable song, and,at this age, LMAN lesions do not affect song quality in male zebrafinches (Bottjer et al., 1984; Scharff and Nottebohm, 1991).

The slice preparation procedure has been described previously in detail (Mooney and Konishi, 1991). Briefly, the bird wasdecapitated after ketamine injection and Metofane inhalation anesthesia(for some whole-cell experiments, ketamine was omitted, but thepresence or absence of ketamine in the anesthetic regimen didnot alter NMDA receptor-mediated currents). The brain was removedand chilled in artificial CSF (ACSF; 4°C) and then cut sagittallyalong the bifurcation of the midsagittal sinus. Sagittal slicesthat included LMAN were cut at 400 µm thickness on a vibratome(Vibratome Series 1000, Ted Pella, Redding, CA) and immediatelytransferred to an interface-type holding chamber maintained atroom temperature. After 60-90 min, slices were transferred eitherto an interface-type chamber (30°C; Medical Systems, Greenvale,NY) for sharp microelectrode intracellular recordings or to asuperfusion chamber (24°C) for whole-cell recordings. The ACSFperfusate was equilibrated with 95%O₂/5%CO₂. LMAN and the DLMaxons ascending to LMAN were readily visualized under transillumination(Fig. 1B).

ACSF consisted of (in mM) 119 NaCl, 2.5 KCl, 1.3 MgCl₂, 2.5 CaCl₂, 1 NaH₂PO₄, 26.2 NaHCO₃, and 11 glucose. Equiosmolar sucrosewas substituted for NaCl during the tissue preparation stage.

Electrophysiological recordings. Stable sharp intracellular recordings (112 cells in 105 slices from 50 animals), which wereclassified as those in which the membrane potential of a cellwas negative of $-$ 60 mV for a period of 15 or more minutes, wereobtained in brain slices made from male zebra finches throughoutsong development (PHD 22-180). Sharp intracellular recordingswere made with borosilicate glass pipettes (BF100-50-10, SutterInstrument, Novato, CA) pulled to a final resistance of 60-120M $Omega$ and filled with 3 M K-acetate. The electrodes were advancedthrough the slice with a Newport Series 360 Motorizer (NewportInstruments, Fountain Valley, CA), which replaced the fine z-axismicrometer on a Marzhauser MM-33 micromanipulator (Sutter Instrument).Intracellular potentials were amplified with an Axoclamp 2B amplifier(Axon Instruments, Foster City, CA) in bridge mode, low-pass-filteredat 1-3 kHz, and digitized at 10 kHz.

Whole-cell recordings (39 cells in 34 slices from 24 animals) were obtained in brain slices made from male zebra finches throughoutsong development (PHD 22-180). These recordings were made withborosilicate patch pipettes (3-7 M $Omega$ ) coupled to a three-dimensionalhydraulic micromanipulator (Newport Instruments) mated to a mechanicalpositioner (MX110 Siskiyou Design, Soma Scientific Instruments,Irvine, CA). Pipettes were filled with an internal solution consistingof (in mM) 100 Cs⁺-gluconate, 10 EGTA, 5 MgCl₂, 40 HEPES, 2 Na⁺-ATP, 0.3 Na⁺-GTP, and 1 QX-314; the pH was adjusted to 7.25 with CsOH (50%gm/ml H₂O). Whole-cell currents were recorded with an Axopatch1D intracellular amplifier (Axon Instruments), and current traceswere digitized at 10 kHz after low-pass filtering at 1-5 kHz.Series resistance was monitored throughout the recording by measuringthe current transients resulting from small (2 mV) hyperpolarizingvoltage pulses. Holding potentials were not corrected for theliquid junction potential.

Bipolar stimulating electrodes either were made from individual tungsten microelectrodes (Micro Probe, Clarksburg, MD) orwere prefabricated concentric bipolar electrodes (FHC, Brunswick,ME). To stimulate the DLM-LMAN synapse while avoiding accidentalactivation of LMAN axon collaterals in area X, we placed stimulatingelectrodes in regions ventral and caudal to area X. We elicitedsynaptic responses at 0.1 Hz by applying a brief (100 µsec) electricalstimulus (50-650 µA) to the DLM axons. The stimulation protocolused here activated DLM axons, because these are the only knownsource of afferent input to LMAN and because stimulating electrodeswere placed in the region where DLM axons travel to reach theirtarget (Bottjer et al., 1989).

Data acquisition and analysis. Data acquisition and analysis for intracellular recordings were performed with a National Instruments(Austin, TX) data acquisition board (AT-MIO-16E2), controlledby custom LabVIEW software written by Fred Livingston and RobNeummann. Subthreshold responses were measured with hyperpolarizingcurrent pulses (1-2 sec; from $-$ 200 to $-$ 400 pA). Suprathresholdresponses (i.e., those that generated action potentials) weremeasured in response to depolarizing current pulses (1-2 sec,from +100 to +800 pA). Input resistance measurements, calculatedby measuring the steady-state voltage caused by injecting small( $-$ 200 pA) hyperpolarizing current pulses, were made throughoutthe recording session; reported values were measured within thefirst 30 min of a recording session. Membrane potential was measuredduring the first and last few minutes of a recording session;then an average of these two values was obtained after subtractingthe membrane potential offset (determined after exiting the cell)from the latter value. Average firing rates were measured in responseto 1- to 2-sec-long depolarizing currents. AHPs after a currentpulse were identified as excursions of the membrane potentialthat traveled negative of the prestimulus baseline. Synaptic currentsand potentials shown here are the averages of three to nine individualevents, unless otherwise specified.

NMDA receptor-mediated EPSCs were recorded in 2.5 µM NBQX and 50 µM picrotoxin and were evoked while the membrane potentialwas held 20 mV more positive than the empirically determined EPSCreversal potential (E_rev) to remove the voltage-dependent blockadeby extracellular magnesium (Mayer et al., 1984; Nowak et al.,1984). Decay time constants of NMDA receptor-mediated EPSCs wereestimated by fitting the falling phase of the current with a double-exponentialdecay function, y = y₀ + A₁e^(x  x₀^)/₁ + A₂e^(x  x₀^)/₂, constrained to baseline (Origin, Microcal Software, Northampton,MA); double-exponential fits of the NMDA EPSCs always providedlower $chi$ ² values than did single-exponential fits. These double-exponentialfits yielded four variables: a time constant ( $tau$ ₁) and its relativeamplitude (A₁) for a fast component, and a time constant ( $tau$ ₂)and its relative amplitude (A₂) for a slow component. The percentageof the slow component was calculated by the equation (A₂/(A₁+A₂))·100.EPSC rise times were calculated as the time between 10 and 90%of the peak amplitude. One-way ANOVAs and two-tailed Student'st tests (Origin) were used to test for significance; the resultsof these analyses are reported in the tables and the figure legends.

Drug application. During interface recordings, drugs were applied from a puffer pipette manufactured from 1.5 mm borosilicateglass, pulled to a tip diameter of 20-50 µm, and loaded with thedrug dissolved in ACSF. The pipette was coupled to a Picospritzer(General Valve, Fairfield, NJ), which was used to eject a smalldrop of the drug onto the slice. Drug concentrations were D-APV(D( $-$ )-2-amino-5-phosphonopentanoic acid), 400-800 µM; NBQX (1,2,3,4-tetrahydro-6-nitro-2,3-dioxo-benzo(f)quinoxaline-7-sulfonamidedisodium), 25-50 µM; picrotoxin, 200 µM; and NiSO₄(NH₄)₂SO₃, 10mM. The actual concentration of the drug at the recording sitewas assumed to be substantially lower. Drug application for whole-cellexperiments was accomplished by bath perfusion of the drug. Inthese experiments the bath (i.e., final) concentrations of drugswere D-APV, 50-100 µM; NBQX, 2.5-5 µM; and picrotoxin, 50 µM.

Histology of LMAN neurons. Neurobiotin (4-6% for sharp microelectrodes and 0.5% for whole-cell pipettes) was used for allintracellular recordings. Depolarizing currents (+ 0.5-1.5 nA,1 sec in duration at 2 sec intervals) were applied for 15-20 minat the end of each recording session. Then the slice was fixedin 4% paraformaldehyde in 25 mM sodium phosphate buffer for 12-16hr at 4°C, resectioned on a freezing microtome at 75 µm, and visualizedwith avidin-HRP (diluted 1:100; Vector Laboratories, Burlingame,CA) and 3 $'$ 3 $'$ -diaminobenzidine tetrahydrochloride; the reactionwas intensified with 1% CoCl₂ and 1% NiSO₄(NH₄)₂SO₃. Camera lucidadrawings were made on a Zeiss microscope (Oberkochen, Germany),using a 63× objective. After reconstruction, sections were counterstained(cresyl violet) to confirm that cells were located within theboundaries of the nucleus.

Reagents. All reagents for ACSF were obtained from Mallinckrodt Specialty Chemical (Paris, KY); D-gluconic acid and picrotoxinwere from Sigma (St. Louis, MO); CsOH was from Aldrich Chemical(Milwaukee, WI); NiSO₄(NH₄)₂SO₃ was from Fisher Scientific (Pittsburgh,PA); all other drugs were obtained from Research BiochemicalsInternational (Natick, MA).

RESULTS
Sharp microelectrode recordings initially were used to characterize the intrinsic and synaptic properties of LMAN neurons,because this technique was most reliable for obtaining stablerecordings in zebra finch tissue of all ages. In addition, whole-cellvoltage-clamp recordings were used to characterize more completelyevoked synaptic currents without the confounding effects of activeconductances in the postsynaptic cell. Of 112 LMAN neurons studiedwith sharp microelectrodes, 80 were from adults, 16 were fromjuveniles, and 16 were from fledglings. Of the 39 cells studiedusing whole-cell pipettes, 13 were from adults, 8 were from juveniles,and 18 were from fledglings.

Neurobiotin staining revealed that almost all (75 of 80) of the LMAN neurons from which there were recordings had spinousdendrites and a main projection axon that divided into two branches;one of the branches traveled ventrally toward area X, while theother branch exited LMAN caudally in the tract that contains LMANaxons projecting to RA (Figs. 2A, 4A). At a much lower frequency(5 of 80 cells), we also encountered a class of smaller neuronswith thin dendrites that we tentatively identified as interneurons,but these were not included in any further analysis.
Fig. 2. The morphology and subthreshold and suprathreshold responses of an adult LMAN projection neuron. A, Camera lucida reconstructionof a neurobiotin-stained neuron of the type encountered in thisstudy. LMAN projection neurons have spinous dendrites, local collaterals,and a bifurcated primary axon, with one process traveling caudallytoward RA and the other ventrally toward area X (dashed linesrepresent missing portions of axons). The inset on the right isa low-power camera lucida reconstruction showing the same LMANneuron in its relation to the borders of LMAN and area X (dorsalis toward the upper right, and rostral is toward the lower right).Scale bar, 20 µm; 200 µm for inset. B, Adult LMAN neurons typicallyfired action potential trains that accommodated in response todepolarizing currents, as shown in the top two traces. Inwardrectification (marked by an asterisk) often occurred in responseto the larger hyperpolarizing currents, as shown in the thirdset of traces. Resting potential = 76 mV. C, The instantaneousfiring frequency is shown plotted as a function of the spike intervalnumber and is well fit by a straight line [average correlationcoefficient for the adult population, in response to +600 pA,was r = $-$ 0.93 ± 0.01 (n = 39)]. The average correlation coefficientfor the juvenile population, in response to +600 pA, was r = $-$ 0.86± 0.03 (n = 12).
[View Larger Version of this Image (31K GIF file)]

Fig. 4. The morphology and sub- and suprathreshold responses of a fledgling LMAN projection neuron. A, Camera lucida reconstructionof a neurobiotin-stained fledgling projection neuron reveals similarmorphology to adult neurons, including the spinous dendrites,local collaterals, and the bifurcating main axon with projectionsto area X and RA. The inset on the right is a low-power cameralucida reconstruction showing the same LMAN neuron with respectto the borders of LMAN (dorsal is toward the top of the figure;rostral is toward the right). Scale bar, 20 µm; 200 µm for inset.B, Fledgling LMAN projection neurons fired action potentials intwo distinct modes in response to depolarizing current. In thetop trace a fledgling neuron fired in a bursting manner (Mode1) in response to depolarizing current injection. However, ata separate time during the recording session, the same neuronfired accommodating action potential trains (Mode 2) that weresimilar to those of adult neurons, as shown in the bottom trace.Note that the membrane potential shifted from $-$ 76 to $-$ 71 mV inparallel with the shift in firing modes. C, The instantaneousfiring frequency is shown plotted as a function of the spike intervalnumber. For cells firing in mode 2, this relationship was wellfit by a straight line [r = $-$ 0.93; average correlation coefficientfor the fledgling population, in response to +400 pA, was r = $-$ 0.80 ± 0.07 (n = 6)]. However, cells that fired in Mode 1 hadrapidly changing instantaneous firing frequencies and were poorlyfit by a straight line (fit not shown).
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Intrinsic properties
Adult LMAN projection neurons had an average resting potential of $-$ 76 ± 1 mV (mean ± SEM) and an average input resistanceof 90 ± 4 M $Omega$ (Table 1). Depolarizing current pulses could producetrains of action potentials that accommodated over the periodof the applied pulse (Fig. 2B), and the relationship between instantaneousspike frequency and spike interval number was fit by a straightline (Fig. 2C). In addition, the average firing rate of theseaction potential trains increased in a linear manner over therange of current pulses routinely applied (Fig. 3). Afterhyperpolarizations(AHP) following spike trains were observed in some cells (Fig.5A, Table 1), and an inward rectification component often wasobserved (Table 1) in response to hyperpolarizing current pulses(asterisk in Fig. 2B; see also Table 1).

Table 1. Intrinsic properties

Parameter Fledgling: 27-32 PHD (mean = 30, n = 16 cells from 15 slices) Juvenile: 40-51 PHD (mean = 43, n = 16 cells from 16 slices) Adult: 90-180 PHD (mean = 13, n = 75 cells from 74 slices)

V_rest (mV ± SEM)^a $-$ 77 ± 2, n = 12 $-$ 76 ± 2, n = 16 $-$ 76 ± 1, n = 59

Input resistance (M $Omega$ ± SEM)^b 82 ± 8, n = 13 98 ± 9, n = 16 90 ± 4, n = 59

Accommodation (Y/N) Y Y Y

Bursting cells 80% (12/15) 7% (1/15) 0% (0/69)

AHP 50% (8/16) 60% (9/15) 33% (19/58)

Inward rectification 70% (7/10; 6 nd) 89% (8/9; 6 nd) 64% (29/45)

nd = not determined. One-way ANOVAs: ^a F = 0.02, p > 0.97; ^b F = 1.1, p > 0.33.

Fig. 3. Average action potential firing frequencies for different depolarizing currents (1-2 sec in duration) from LMAN neurons ofvarious ages. The average action potential firing frequencieswere calculated for fledgling (stars; n = 15), juvenile (filledcircles; n = 14), and adult (open circle; n = 55) LMAN neuronsand were plotted as a function of the injected current. Linearfits of the data from each age are shown; the firing rate in responseto a given amount of injected current did not differ among theage groups. One-way ANOVAs demonstrated that the responses werenot significantly different across ages at +200 pA (F = 0.2, p> 0.8), +400 pA (F = 0.5, p > 0.6), and +600 pA (F = 0.5, p >0.6).
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Fig. 5. The effect of membrane potential on bursting in fledgling neurons. A, Hyperpolarization could unmask the bursting behaviorin fledgling LMAN neurons. Initially, current injection (+400pA) induced only the mode 2 adult-like firing in this fledglingneuron, as shown in the left trace. However, when the membranewas subjected to tonic hyperpolarization ( $-$ 300 pA), the same depolarizingcurrent (i.e., +400 pA) caused the neuron to fire in mode 1, asshown in the right trace. B, Hyperpolarization also could augmentpreexisting bursting behavior in fledgling LMAN neurons. The twoleft traces show a fledgling LMAN neuron that initially firedin mode 1 in response to depolarizing currents (+300 and +600pA). When the same cell was subjected to tonic hyperpolarization( $-$ 300 pA), as shown in the right two traces, bursting was augmentedin response to the +600 pA current injection, although the cellremained subthreshold when injected with the +300 pA current.
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The intrinsic properties of juvenile LMAN projection neurons were quite similar to those of adults. The average resting membranepotential of juvenile neurons was $-$ 76 ± 2 mV, and the averageinput resistance was 98 ± 9 (Table 1). As in the adults, thespike trains evoked by depolarizing currents underwent accommodation,such that the relationship between instantaneous spike frequencyand spike interval number was best fit by a straight line (seelegend in Fig. 2). In addition, the average firing rate of theseaction potential trains increased in a linear manner over therange of applied depolarizing current pulses (Fig. 3). Inwardrectification was exhibited in juvenile neurons in response tohyperpolarizing current pulses, and AHPs also were often observedin these cells (Table 1). Finally, one LMAN neuron recorded fromanimals in this age group had suprathreshold firing propertieslike those described for fledgling neurons (see below).

Fledgling LMAN neurons were not significantly different from juvenile and adult cells in their resting potentials ( $-$ 77 ± 2mV) and input resistances (85 ± 7 M $Omega$ ; see Table 1 for statisticalcomparisons). In direct contrast to the adult and juvenile neurons,however, individual fledgling LMAN projection neurons (Fig. 4A)often fired in a bursting mode in response to depolarizing currents(mode 1; 12 of 15 cells; Figs. 4B). Of the 12 fledgling LMAN neuronsthat displayed the bursting mode, eight cells fired in this modewhen depolarized from the actual resting potential. In the otherfour cells the bursting mode appeared only when the depolarizingpulses were preceded by tonic hyperpolarization (Fig. 5A). Regardless,depolarization-induced bursting was enhanced by previous hyperpolarization(Fig. 5B).

Fledgling LMAN neurons also could fire in a mode that was similar to those seen at older ages (mode 2; 9 of 15 cells; Fig.4B). In addition to the four cells that could be transformed frommode 2 to mode 1 by previous hyperpolarization, three cells firedonly in mode 2 throughout the recording, whereas two other cellsspontaneously switched between the two firing modes (see, forexample, Fig. 4B). In mode 2, the instantaneous firing frequencywas a linear function of the interspike interval (Fig. 4C), andthe average spike frequency increased in a linear manner withrespect to the injected current amplitude as seen in juvenilesand adults (Fig. 3; see figure legend for statistical comparison).In summary, individual fledgling LMAN projection neurons couldexhibit two distinct modes of firing in response to depolarizingcurrents, including a bursting mode that was never observed inadult LMAN neurons at normal resting potentials (n = 60 cells)or after previous hyperpolarization (n = 9 cells).

We sought to clarify the ionic basis of the mode 1 action potential firing, which resembles a bursting behavior that has beenobserved in other cell types (see Discussion). Because nickelis known to block such bursting behavior (Fox et al., 1987), weapplied nickel (10 mM) directly to LMAN via a puffer pipette.Nickel application reversibly blocked the bursting component ofthe response to suprathreshold depolarizing currents while leavingthe cell with its ability to fire action potentials intact (Fig.6; five of five cells were blocked, three with at least partialrecovery). In the presence of nickel, fledgling LMAN neurons thatpreviously had fired in mode 1 now exclusively exhibited mode2 action potential discharges. The enhancing effects of previoushyperpolarization and the blocking effects of nickel stronglysuggest that a low-threshold calcium spike (LTS) contributes tothe action potential bursting that we have seen in fledgling LMANprojection neurons.
Fig. 6. Mode 1 firing was blocked by extracellular application of nickel. This fledgling LMAN neuron fired in mode 1 in response todepolarizing current (left trace). Nickel (10 mM, applied viaa puffer pipette) blocked the bursting behavior of this cell (middletrace). Sixty minutes after the nickel application the burstingbehavior partially recovered (right trace). Resting potential= $-$ 75 mV.
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Synaptic properties
To investigate the functional properties of the synapse between DLM axons and LMAN neurons, we evoked synaptic responses fromLMAN projection neurons by electrically stimulating ascendingthalamic axons in brain slices prepared from animals PHD 22-180.Initial experiments were performed with sharp microelectrodesto record postsynaptic potentials (PSPs) elicited within LMANby thalamic fiber stimulation. Subsequent experiments used thesuperior voltage control afforded by the whole-cell techniqueto establish the contribution of NMDA receptors to the evokedsynaptic current and to determine whether the kinetics of theseNMDA receptor-mediated currents change over the course of development.

Electrical stimulation of DLM axons routinely elicited PSPs from LMAN projection neurons at all ages. At lower stimulus intensities,these responses consisted of a short-latency monotonic PSP thatwas depolarizing (Fig. 7). Because this PSP could drive the cellto spike if the postsynaptic membrane was sufficiently depolarized(data not shown), it was classified as an EPSP. In most cells,higher stimulus strengths could elicit the short-latency EPSPand also a longer-latency hyperpolarizing component, which wasclassified as an IPSP (marked by an asterisk in Fig. 7). ThisIPSP grew in amplitude as the stimulus intensity was increased(Fig. 7).
Fig. 7. Excitatory and inhibitory synaptic responses could be elicited from LMAN projection neurons by electrical stimulation of DLMaxons. Synaptic potentials were elicited in LMAN projection neuronsin response to increasing stimulus intensities (100 µsec duration;stimulus artifact marked by arrow; the stimulus amplitude foreach trace is shown on the right). At threshold (~300 µA) onlyan EPSP was elicited. At higher stimulus intensities an IPSP alsowas elicited (marked by asterisk).
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To determine the contribution of postsynaptic glutamate receptors to the EPSPs elicited within LMAN by stimulating thalamicfibers at lower intensities, we focally applied glutamate receptorantagonists directly to LMAN with a puffer pipette. In slicesprepared from adult and juvenile birds, the application of theAMPA receptor antagonist NBQX (25 µM) reversibly blocked the EPSPelicited by stimulating thalamic fibers (Fig. 8, Table 2). Inthe presence of NBQX, a smaller, slower EPSP, reminiscent of NMDAreceptor-mediated EPSPs, often was observed (trace 2, Fig. 8).Consistent with this view, the NMDA receptor antagonist D-APVcould depress longer-latency components of the EPSP (~10-20 msecafter stimulus; compare traces 3&4, Fig. 8; see also Table 2).These results suggest that both AMPA and NMDA receptors contributeto thalamically driven EPSPs within LMAN.
Fig. 8. EPSPs evoked in LMAN by thalamic fiber stimulation were blocked by glutamate receptor antagonists. An evoked EPSP (trace 1;arrow marks stimulus artifact) was reduced substantially (trace2) by NBQX (25 µM), an antagonist of the AMPA subtype of glutamatereceptor. The EPSP amplitude recovered after ~75 min (trace 3).Subsequent application of D-APV (400 µM) only slightly reducedthe EPSP amplitude (trace 4), which recovered completely after~50 min (trace 5). Traces 1&2 and traces 3&4 are overlaid to facilitatethe comparison of the drug effects. Traces 3 and 4 were subtractedto yield the D-APV-sensitive EPSP, and the resulting trace wasoverlaid with NBQX-insensitive EPSP (traces 3-4&2), revealingthat they have a similar amplitude and time course. The bottomportion of the figure plots the EPSP amplitude over the courseof the experiment (synaptic responses were evoked at 0.1 Hz; meanresting potential = $-$ 75 mV).
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Table 2. Current-clamp synaptic properties

Age (PHD) Control (mV ± SEM) NBQX Recovery Control APV Recovery

Juvenile: 40-51 9.1 ± 2.2, n = 5 cells 2.4 ± 0.6^a 9.2 ± 1.9 nd nd nd

Adult: 90-180 9.9 ± 1.3, n = 9 cells 2.6 ± 0.6^b 8.8 ± 1.0 9.0 ± 1.5, n = 5 cells 7.4 ± 1.4^c 9.4 ± 1.9

nd = not determined. Two-tailed t tests, compared with controls: ^a p < .001; ^b p < .0001; ^c p < .005.

In addition to driving glutamatergic EPSPs, higher intensity thalamic fiber stimulation also evoked IPSPs within LMAN (trace1, Fig. 9). As with evoked EPSPs, the combined EPSP-IPSP was blockedby NBQX (trace 2, Fig. 9). In contrast, the GABA_A receptor antagonistpicrotoxin (PTX) blocked the IPSP while leaving the EPSP intact(trace 6, Fig. 9; see also Fig. 10). Because these evoked IPSPswere blocked by both NBQX and PTX, thalamic axons most likelydrive feedforward inhibition via an excitatory synapse locatedon a GABAergic interneuron within LMAN.
Fig. 9. Both AMPA and GABA_A receptor antagonists blocked IPSPs elicited in LMAN by electrical stimulation of thalamic axons. An evokedcompound EPSP-IPSP (trace 1; arrow marks stimulus artifact) wasblocked (trace 2) by NBQX (25 µM); the compound response partiallyrecovered after ~50 min (trace 3). In contrast, the applicationof D-APV (800 µM) had no effect on either the EPSP or the IPSP(traces 4 and 5). The application of picrotoxin (PTX; 200 µM)selectively eliminated the IPSP, leaving only the EPSP (trace6). The remaining EPSP was reduced substantially by the applicationof NBQX (25 µM; trace 7), followed by a partial recovery (trace8). Traces 1&2 and traces 5&6 are overlaid to facilitate comparisonof the drug effects. The bottom two portions of the figure plotthe PSP amplitude and onset slope over the course of the experiment(synaptic responses were elicited every 10 sec; average restingpotential = $-$ 79 mV)
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Fig. 10. Whole-cell voltage-clamp recordings (holding potential specified to the left) showed that thalamic fiber stimulation (markedby arrow in bottom left trace) could evoke glutamatergic EPSCsthat were blocked by the AMPA receptor antagonist NBQX, GABAergicIPSCs, and voltage-dependent NMDA receptor-mediated EPSCs fromLMAN neurons. At V_h = $-$ 30 mV (relative to E_rev; see Materialsand Methods), the evoked EPSC was inward-going, whereas the IPSCwas outward. The GABA_A receptor blocker picrotoxin (PTX; 50 µM)blocked the IPSC, leaving a fast inward current that was blockedby the AMPA receptor antagonist NBQX (2.5 µM). The remaining slowerinward current, which increased in amplitude when the cell washeld at 0 mV, was blocked by the NMDA receptor antagonist D-APV(50 µM). In LMAN, NMDA receptor-mediated EPSCs reversed positiveof 0 mV (see Table 3), suggesting that the synaptic membranewas more negative than the reported values because of incompletespace clamp.
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Developmental changes in NMDA receptor-mediated EPSCs
Whole-cell voltage-clamp recordings were used to characterize NMDA receptor-mediated EPSCs in LMAN, because this techniquepermitted greater control of postsynaptic membrane potential thandid sharp electrodes. This approach was necessary because NMDAEPSCs are strongly attenuated at negative membrane potentials(Mayer and Westbrook, 1984; Mayer et al., 1984; Nowak et al.,1984), and LMAN neurons rest at relatively negative voltages (seeTable 1). Whole-cell voltage-clamp recordings revealed that electricalstimulation of thalamic fibers could evoke both excitatory andinhibitory responses in LMAN (Fig. 10). At holding potentials between $-$ 40 and 0 mV, stimulation elicited a short-latency inward currentas well as a longer-latency outward current. This longer-latencyIPSC was abolished by the bath application of PTX (n = 16; 4 adult,5 juvenile, 7 fledgling), leaving only the shorter-latency inwardEPSC, which was blocked by the subsequent application of NBQX(n = 16; 4 adult, 5 juvenile, 7 fledgling). Although little inwardcurrent could be detected at negative holding potentials (i.e., $-$ 30 mV) in the presence of NBQX, a slower inward current couldbe detected in the presence of AMPA and GABA_A receptor antagonistsat more positive holding potentials (i.e., 0 mV; trace markedby an asterisk in Fig. 10; n = 12 of 13 adult cells, 12 of 13 juvenilecells, and 17 of 18 fledgling cells). The negative slope conductanceof the evoked EPSCs recorded within LMAN is typical of NMDA receptor-mediatedEPSCs, and the attenuating effects of postsynaptic hyperpolarizationindicate that NMDA receptors are located on the postsynaptic celland not on an interposed neuron. Although these evoked EPSCs reversedpositive of 0 mV (see Table 3), presumably because of inadequatespace clamp, application of the NMDA receptor blocker D-APV reversiblyabolished the evoked EPSCs that persisted in the presence of PTXand NBQX (Fig. 10; n = 4 of 4 adult, 3 of 3 juvenile, and 3 of3 fledgling). These recordings show that thalamic fiber stimulationcan evoke NMDA receptor-mediated EPSCs within LMAN throughoutsong development (PHD 22-166).

Table 3. Properties of NMDA receptor-mediated EPSCs (V_h = +20 mV, relative to E_rev)

Parameter Fledgling: 22-32 PHD (mean = 28, n = 9 cells from 9 slices) Juvenile: 40-51 PHD (mean = 44, n = 8 cells from 8 slices) Adult: 90-180 PHD (mean = 136, n = 8 cells from 8 slices)

Amplitude (pA ± SEM)^a 85 ± 13 123 ± 45 70 ± 13

Decay $tau$ ₁ (msec ± SEM)^b 42 ± 6 39 ± 4 32 ± 2

Decay $tau$ ₂ (msec ± SEM)^c 197 ± 24 208 ± 38 177 ± 16

Slow component (%) (((A2/(A1 + A2))·100) ± SEM)^d^* 50 ± 05 28 ± 04 20 ± 04

10-90% rise time (msec ± SEM)^e 6.5 ± 0.4 6.4 ± 1.1 4.8 ± 0.4

Input resistance (M $Omega$ ± SEM)^f 102 ± 16 98 ± 11 93 ± 11

E_rev (mV ± SEM)^g,h 54 ± 6 49 ± 8 52 ± 4

^a One-way ANOVA (amplitude: F = 1.02, p > 0.37). ^b One-way ANOVA ( $tau$ ₁: F = 1.44, p > 0.25). ^c One-way ANOVA ( $tau$ ₂, F = .3, p > 0.7). ^d Two-tailed t tests: fledgling-adult, p < 0.0003; fledgling-juvenile, p < 0.003; juvenile-adult, p > 0.1. ^e One-way ANOVA (10-90% rise time: F = 1.85, p > 0.18). ^f One-way ANOVA (input resistance: F = 0.11, p > 0.79). ^g One-way ANOVA (E_rev: F = 0.23, p > 0.89). ^h Not corrected for the liquid junction potential. ^* Significantly different.

Several synaptic pathways that undergo experience-dependent changes during early development also exhibit an age-dependentdecrease in the duration of their NMDA receptor-mediated currents(Carmignoto and Vicini, 1992; Hestrin, 1992; Ramoa and McCormick,1994; Crair and Malenka, 1995). To determine whether similar developmentalchanges occur within LMAN, we measured the NMDA component of theevoked EPSC by bathing the slice in NBQX (2.5 µM) and PTX (50µM) while holding the postsynaptic membrane 20 mV positive ofthe reversal potential to relieve voltage-dependent block by extracellularmagnesium. In these conditions evoked EPSCs at all ages were wellfit with a double-exponential function, yielding a fast and aslow decay time constant (Fig. 11A, Table 3). These analyses showthat the slow component constituted a significantly larger fractionof the total current in fledgling neurons than it did in juvenileand adult neurons (Fig. 11A,B, Table 3) and that the transitionto the faster decay kinetics is complete in large part by PHD40 (Fig. 11B). This difference in decay kinetics was apparent althoughthe actual values of the two time constants remained constantthroughout development (Fig. 11C, Table 3). In contrast to thechange in decay kinetics, neither EPSC rise times nor input resistanceschanged significantly during development (Table 3), strengtheningthe hypothesis that the observed differences in decay kineticsare attributable to underlying differences in NMDA receptor properties.These results show that the decay kinetics of NMDA receptor-mediatedEPSCs evoked within LMAN change markedly over the course of earlysong development (PHD 32-40).
Fig. 11. The decay kinetics of NMDA receptor-mediated EPSCs elicited in LMAN by thalamic fiber stimulation change during early development.A, On the left is an evoked NMDA receptor EPSC from a fledglingLMAN projection neuron, and on the right is a NMDA receptor EPSCfrom that of an adult. These NMDA receptor-mediated EPSCs werebest fit by double exponentials, which are represented by theopen circles. The black curves represent the fast ( $tau$ ₁) and slow( $tau$ ₂) exponentials that constitute the double-exponential fit (fledgling: $tau$ ₁ = 45 msec, $tau$ ₂ = 245 msec, A₁ = 17, and A₂ = 25.1; adult: $tau$ ₁= 38 msec, $tau$ ₂ = 175 msec, A₁ = 45.3, and A₂ = 18.6; see Materialsand Methods). The slow component constituted a significantly largerfraction of the total synaptic current in the fledgling than ineither the juvenile or adult [EPSCs were recorded in the presenceof NBQX (2.5 µM) and picrotoxin (50 µM) at V_h = +20 mV of E_rev].B, The percentage of the falling phase of the total response amplitudeconstituted by the slow component of the double-exponential fitdeclined with age [(A₂/(A₁+A₂))·100; see Materials and Methodsand Table 3 for further details]. C, Fast and slow time constants( $tau$ ₁ and $tau$ ₂) from the double-exponential fits did not change significantlyas a function of age (see Materials and Methods and Table 3 forfurther details).
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DISCUSSION
This study shows that LMAN neurons undergo distinct changes in their intrinsic and synaptic electrophysiological propertiesbetween the fledgling and juvenile stages of life (PHD 32-40).LMAN projection neurons in fledgling zebra finches can displaytwo modes of action potential firing, including a bursting modethat is not expressed in the same class of neurons in the juvenileand adult. In addition, the decay kinetics of NMDA receptor-mediatedEPSCs in LMAN become markedly faster between PHD 32-40. The timecourse of these changes contrasts with our original hypothesisthat such physiological changes should extend into later sensorimotorlearning (i.e., PHD 50-90). Therefore, if such changes are pertinentto song development, they must relate to earlier events, suchas sensory acquisition and the initial stages of sensorimotorlearning, rather than later periods of vocal plasticity and theprocess of song crystallization.

Intracellular neurobiotin staining revealed that the recordings made here are from LMAN projection neurons. These cells haveaxon branches that project toward area X and nucleus RA, consistentwith anatomical tracing experiments that show that many individualLMAN neurons project to both targets (Nixdorf-Bergweiler et al.,1995a; Vates and Nottebohm, 1995). In addition, these neuronshave radially symmetric spinous dendrites and are thus likelyto be the same class as those spinous cells identified in Golgistudies that undergo an age-dependent decrease in spine frequency(Nixdorf-Bergweiler et al., 1995b). A preliminary analysis ofthe morphology of LMAN projection neurons labeled here indicatesthat, although they undergo a similar developmental decrease inspine frequency, the overall extent of their dendritic arborsis remarkably constant across these ages (Stacy et al., 1997).

Despite their similar dendritic morphologies, resting potentials, and input resistances, adult and fledgling LMAN projectionneurons differed markedly in their suprathreshold responses todepolarizing currents. Adult neurons fired trains of action potentialsin response to depolarization that accommodated over the durationof the injected current pulse. This accommodation was characterizedby a linear relationship between the instantaneous spike frequencyand the spike interval number. In contrast, fledgling neuronsdisplayed a burst mode of firing in response to similar depolarizingcurrents (mode 1) as well as in some instances firing in an adult-likemanner. The two modes of firing exhibited by fledgling LMAN neuronsare thought to reflect the behavior of a single cell class because(1) two cells spontaneously switched from mode 2 to mode 1 duringthe recording (see, for example, Fig. 4B), (2) four cells thatinitially exhibited the linear mode could be induced to burstby previous hyperpolarization (Fig. 5A), and (3) the morphologiesof cells displaying either or both firing modes were those ofLMAN projection neurons.

Mode 1 firing is reminiscent of several other forms of burst firing, including that described for adult X-projecting HVc neurons(Kubota and Saito, 1991), mammalian thalamic neurons (Jahnsenand Llinás, 1984), and neocortical pyramidal neurons (Silva etal., 1991; Gray and McCormick, 1996). As in these other cell types,the mode 1 firing of fledgling LMAN neurons involves a putativeLTS, because it is blocked by nickel (Fox et al., 1987) and augmentedby previous hyperpolarization. Modulatory factors that can elicithyperpolarization, such as norepinephrine, have been shown toaugment LTS-dependent bursting in the mammalian thalamus (McCormick,1989). In the song system, tyrosine hydroxylase, an enzyme essentialto catecholamine production, as well as certain adrenergic receptors,has been localized to LMAN (Bottjer, 1993; Ball, 1994; Soha etal., 1996). Further studies will be required to determine whethernorepinephrine or other modulatory factors influence burstingin fledgling LMAN neurons.

In the zebra finch, bursting correlates both with sensory acquisition, which can be complete as early as PHD 35 (Bohner, 1990),and early sensorimotor learning, which begins between PHD 28-40(Immelmann, 1969; Arnold, 1975). Burst firing in presynaptic cellshas been shown to increase the probability of eliciting a postsynapticresponse (Miles and Wong, 1986; Stevens and Wang, 1995). In LMAN,this mechanism might facilitate auditory responses to the tutorsong during sensory acquisition or augment signaling to RA duringearly sensorimotor learning. However, the bursting behavior disappearsbefore the time when LMAN lesions fail to disrupt song developmentand well before sensorimotor learning is complete (Bottjer etal., 1984; Scharff and Nottebohm, 1991), arguing against its rolein the later stages of plastic song.

This study provides the first characterization of synaptic transmission within nucleus LMAN and shows that synapses betweenDLM and LMAN are functional by PHD 22. DLM axons evoke excitatorysynaptic responses from LMAN projection neurons and also activatea feedforward inhibitory pathway within LMAN (also see Boettigerand Doupe, 1996). This excitatory drive is mediated by a combinationof AMPA and NMDA receptors located on LMAN projection neurons,whereas the inhibitory drive is mediated by a GABAergic synapse,because it is blocked by the GABA_A receptor blocker picrotoxin.Inhibition is likely to be polysynaptic because it is also blockedby application of AMPA receptor antagonists, contrary to the expectedeffect if thalamic axons made direct inhibitory contacts ontoLMAN projection neurons. The most parsimonious explanation isthat DLM axons activate AMPA receptors located on GABAergic interneuronswithin LMAN.

DLM axons directly activate NMDA receptors located on LMAN projection neurons. The identification of inputs that activateNMDA receptors within LMAN is specifically relevant, because theinfusion of NMDA receptor antagonists into the neostriatal region(which includes LMAN) of young zebra finches during tutoring disruptssubsequent song development (Basham et al., 1996) and becauseNMDA receptor density within LMAN declines with maturation (Aamodtet al., 1992; Basham, 1996). Therefore, a major site where NMDAreceptor antagonists could disrupt song development is at thesynapse between DLM axons and LMAN projection neurons.

The decay kinetics of NMDA receptor-mediated EPSCs in LMAN become markedly faster over development. These changes could reflectdevelopmental differences in the relative composition of the receptorpopulation, changes in the kinetics of individual NMDA receptors,the disproportionate loss of NMDA receptors from distal processes,or changes in postsynaptic filtering of synaptic currents. Theselatter two factors are unlikely to be significant because thedevelopmental loss of dendritic spines (a major location of NMDAreceptors; see Connor et al., 1994; Petralia et al., 1994) onLMAN neurons does not appear to selectively involve distal processes(Nixdorf-Bergweiler et al., 1995b). Also, unlike the change indecay kinetics, the rise times of these EPSCs do not change significantlyduring development, which contrasts with the expected effectsof altered dendritic filtering (Spruston et al., 1994). Therefore,NMDA receptor-mediated currents could become faster because ofchanges in individual receptors (Monyer et al., 1992), perhapsbecause of differential expression of NMDA receptor subunits,as has been described in the developing mammalian brain (Williamset al., 1993; Monyer et al., 1994). In support of this view, ifenprodil,which binds with high affinity to NMDA receptor heteromultimerscontaining the NR2B subunit, has been shown to bind at significantlygreater levels in the LMAN of PHD 30 male zebra finches relativeto adults (Basham et al., 1997).

Developmental changes in the time course of NMDA receptor-mediated currents occur at several central synapses that undergoactivity-dependent development. At mammalian retinocollicularand thalamocortical synapses, NMDA receptor-mediated EPSCs becomemore rapid as sensitive periods for activity-dependent remodelingcome to a close (Carmignoto and Vicini, 1992; Hestrin, 1992; Ramoaand McCormick, 1994; Crair and Malenka, 1995). In the zebra finchthe change in NMDA receptor kinetics in LMAN occurs between PHD30-40, which is a pivotal time for synaptic remodeling in LMAN.Golgi studies indicate that LMAN neurons undergo a significantincrease in spine frequency between PHD 21-35 and then declinegradually to adult levels thereafter (Nixdorf-Bergweiler et al.,1995b). Our data show that slower NMDA decay kinetics are presentduring the early increase in dendritic spine frequency and thatfaster kinetics correlate with the period of spine frequency reductionin LMAN. When zebra finches are raised in acoustical isolation,the decrease in spine frequency fails to occur (Wallhausser-Frankeet al., 1995), and the period of sensory acquisition is extended(Eales, 1985; Morrison and Nottebohm, 1993). If these differentNMDA EPSC phenotypes facilitate dendritic remodeling in LMAN,then acoustical isolation should delay the transition from fledglingto adult NMDA receptor decay kinetics just as the change in spinefrequency is halted. Finally, if the slower currents typical offledgling LMAN neurons are specifically required for synapticchanges during song learning, then their role must be limitedto early events, such as sensory acquisition and the onset ofsensorimotor learning, but not to the later stages of plasticsong, including crystallization.

FOOTNOTES

Received July 25, 1997; revised Sept. 12, 1997; accepted Sept. 17, 1997.

This research was supported by National Institutes of Health Grant 5T32-GM08441 to F.S.L. and National Institutes of HealthGrant DC02524 and a McKnight Foundation Award to R.M. We thankJohn Spiro, Stephanie White, Matt Kittelberger, Merri Rosen, LoriMcMahon, Felix Schweizer, and two anonymous reviewers for providingthoughtful comments on earlier versions of this manuscript. Wegive special thanks to Rebecca Stacy for expert camera lucidareconstructions of LMAN neurons and to Michael Booze for skilledhistology.

Correspondence should be addressed to Dr. Richard Mooney, Department of Neurobiology, Box 3209, Duke University Medical Center,Durham, NC 27710. E-mail: mooney{at}neuro.duke.edu

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