RespiratoryandTelencephalicModulationo

Respiratory and Telencephalic Modulation of Vocal Motor Neurons in the Zebra Finch

http://www.100md.com 《神经科学杂志》2003年第3期

     ¹ Department of Neurobiology, Duke University Medical Center, Durham, North Carolina 27710, and ² Division of Anatomy, Faculty of Medical and Health Sciences, University of Auckland, Auckland 92019, New Zealandp|@r*, 百拇医药

    ABSTRACTp|@r*, 百拇医药

    Birdsong, like speech, involves coordinated vocal and respiratory activity achieved under telencephalic control. The avianvocal organ, or syrinx, is innervated by motor neurons (MNs) inthe tracheosyringeal part of the hypoglossal nucleus (XIIts) thatreceive their synaptic input from medullary respiratory areasand telencephalic song control areas. Despite the importance ofXIIts MNs to learned vocalizations, little is known about theirintrinsic electrical properties or their synaptic inputs. Therefore,we made in vitro and in vivo intracellular recordings from XIItsMNs in adult male zebra finches to characterize their intrinsicproperties and their synaptic modulation by respiratory and telencephalicareas. In vitro, electrical stimulation of ipsilateral or contralateralmedullary respiratory areas (RAm) routinely evoked glycine receptor-mediatedinhibition in XIIts. With inhibition blocked, similar stimulationevoked excitatory synaptic responses capable of driving sustainedMN firing that was mediated partly by NMDA receptors. These inhibitoryand excitatory inputs likely arise from RAm neurons, because chemicalor electrical stimulation of RAm evoked similar responses in XIIts.In vivo, XIIts MNs displayed rhythmical, expiratory-related activity.EPSPs were pronounced at expiratory onset, but IPSPs were notapparent during inspiration, although XIIts MN firing was suppressed.However, hyperpolarizations as well as excitation were evokedby playback of the bird's own song, a stimulus that potently excitesthe telencephalic song nucleus that innervates XIIts. These findingsilluminate functional properties of the songbird's brainstem circuitryand its specific activation by telencephalic inputs, which couldcoordinate vocal and respiratory activity duringsinging.

    Key words: XIIts; RAm; birdsong; vocal learning; respiration; RAk4z1g, 百拇医药

    Introductionk4z1g, 百拇医药

    Oscine songbirds are one of the few nonhuman taxa to display vocal learning. Song learning, like speech learning, entailsauditory-vocal integration and respiratory-vocal coordinationunder the control of the telencephalon (Doupe and Kuhl, 1999).Surprisingly little is known about synaptic mechanisms underlyingthese functions, although the songbird affords an excellent opportunityfor theirelucidation.k4z1g, 百拇医药

    Birdsong is controlled by a set of interconnected brain nuclei that has as one of its final outputs the tracheosyringeal partof the hypoglossal motor nucleus (XIIts) and its efferent nerve,which innervates the syrinx, the avian vocal organ located atthe confluence of the primary bronchi and trachea (Wild, 1997). Because the XIIts motoneurons (MNs) do not innervatethe tongue but rather muscles that are specifically involved inphonation and respiration and not articulation, they are moreanalogous to mammalian laryngeal than to lingual motoneurons (Wildand Zeigler, 1980; Vicario and Nottebohm, 1988; Dubbeldam andBout, 1990; Vicario, 1991a; Goller and Suthers, 1996a,b). However,because the syrinx and larynx are separate structures in birds,XIIts MNs are not involved in those other behaviors that can engagethe mammalian larynx, such as swallowing (Shiba et al., 1996).This apparent specialization of XIIts for vocalization may simplifythe analysis of XIIts MN synaptic connectivity. XIIts MNs receivesynapses from several sources, including lateral medullary areascontaining respiratory premotor neurons and the nucleus robustusarchistriatalis (RA), a telencephalic structure essential to birdsong(Nottebohm et al., 1976; Wild, 1993a,b). Although the anatomyof these synaptic projections to XIIts is well described, littleis known about theirfunction.

    In quiescent zebra finches (Taeniopygia guttata), XIIts MNs fire in phase with expiration. This respiratory rhythm is thoughtto be driven from lateral medullary regions projecting onto XIItsand containing respiratory premotor neurons (Manogue and Nottebohm,1982; Williams and Nottebohm, 1985; Wild, 1993a; Wild et al.,2000). Still unresolved is whether the XIIts rhythm reflects expiratory-linkedexcitation or inspiratory-linked inhibition, or both. Clarificationof this issue can provide information about how telencephalicand respiratory areas interact to effectvocalization.fk/!, 百拇医药

    During singing, syringeal and respiratory activity are modulated and coordinated (Suthers, 2000), presumably by RA, but theunderlying synaptic mechanisms remain unknown. Middle and ventralRA neurons project topographically onto XIIts MNs that innervateeither dorsal or ventral syringeal muscles, whereas dorsal RAneurons innervate respiratory premotor areas in the lateral medulla,among other targets (Vicario, 1991b; Vicario, 1993; Wild, 1993b;Reinke and Wild, 1998). Furthermore, respiration gates XIIts activityevoked by electrical stimulation of RA or its premotor afferent,HVc (used as a proper name) (Manogue and Nottebohm, 1982). Herewe used in vitro and in vivo intracellular recordings from XIItsMNs to characterize their synaptic inputs from medullary respiratoryareas. Then, we used song playback to assess telencephalic modulationof XIIts and respiratory activity in vivo. These experiments revealfunctional features of XIIts MNs and associated brainstem circuitsthat could coordinate vocal and respiratory activity duringsinging.

    Materials and Methods*9z395, http://www.100md.com

    Subjects. Eighty-five adult (>120 post-hatch d) male zebra finches (Taeniopygia guttata) (23 for in vivo experiments, 62 forin vitro experiments) were used for the experiments, in accordancewith a protocol approved by the Duke University InstitutionalAnimal Care and UseCommittee.*9z395, http://www.100md.com

    Song stimuli. Before the experiment, songs were recorded from a male zebra finch placed with an adult female zebra finch ina recording chamber (Industrial Acoustics, Bronx, NY). Songs wereamplified and low-pass filtered at 10 kHz, digitized at 20 kHz(National Instruments data acquisition board AT-MIO-16E2, Austin,TX), and stored on a hard drive. Songs were recorded and editedwith LabView software (National Instruments; all custom softwarefor this study was written by M. Rosen, F. Livingston, R. Neumann,and R. Balu, Duke University). Edited songs included one to sixmotifs and were ~1-6 sec in duration (a motif is the largest repeatedunit in the bird's song and usually comprises single and multinotesyllables; zebra finch song bouts typically consist of severalmotifs). Stimulus ensembles always included the bird's own song(BOS) and reversed BOS (i.e., song played backward). Forward andreverse versions of the BOS contain the same spectral energy,but differ in both their local and global temporal organization.Previous studies showed that RA projection neurons are potentlyexcited by forward and not reverse BOS playback when the birdis under urethane (Doupe and Konishi, 1991).

    In vivo preparatory surgery. On the morning of the day of the electrophysiological recording, birds were injected in the pectoralmuscle with 20% urethane (90 µl total; Sigma, St. Louis, MO),administered in 30 µl doses at 30 min intervals. Approximately1 hr after the final injection, birds were anesthetized more deeplyvia inhalation of halothane gas (Halocarbon Laboratories, RiverEdge, NJ) and placed in a stereotaxic device (H. Adams, Caltech).After topical application of xylocaine (2.5%) to the scalp andabdomen, the scalp was incised along the midline and a stainlesssteel post was mounted to the rostral part of the bird's skullwith dental cement and super glue, and a pair of Teflon-coatedplatinum-iridium wires (0.007 inch diameter) was inserted intothe abdominal muscles to obtain expiratory electromyograms (EMGs).The bird was transferred to a sound-attenuating chamber (IndustrialAcoustics) mounted on an air table (TMC, Peabody, MA), and thehead was fixed in a metal frame at 45° to the horizontal (Stokeset al., 1974) using the head post. A small craniotomy (<300 µmwide) was made over cerebellar folia corresponding to the locationof the underlying XIIts nucleus, and the dura was torn with afine insect pin (Minuten, Carolina Biological Supply). The birdwas warmed with an electric blanket (37°C; Harvard Apparatus,Holliston,MA).

    In vivo electrophysiology and song presentation. Sharp electrodes (borosilicate glass, BF100-50-10; Sutter Instrument, Novato,CA) were pulled to yield a resistance of 100-200 M"Omega "]mf2$, 百拇医药

    when filledwith 2 M K-acetate and 5% neurobiotin. A hydraulic microdrive(Soma Scientific, Irvine, CA) was used to lower electrodes intothe nucleus (~4 mm depth). Brief (~1 msec) capacitance overcompensationwas used to "ring" the electrode to achieve entry into the cell.An AxoClamp 2B intracellular amplifier (Axon Instruments, FosterCity, CA) was used in bridge mode to record intracellular membranepotentials, which were low-pass filtered at 3 kHz, digitized at10 kHz, and stored on a PC hard drive. XIIts neurons were identifiedon-line by their action potential discharge properties in responseto injected currents (see Results) and by the propensity to generatetrains of action potentials in phase with expiration; in somecases, recording sites were verified histologically after therecording session. Spontaneous membrane potential and EMG recordings,3-5 min long, were collected to inspect for respiratory-linkedaction potential discharge in XIIts MNs. Generally, 10-30 iterationsof each auditory stimulus, delivered at intervals ranging from6 to 10 sec, were presented at ~70 dB (rms, A-weighting) througha speaker positioned 20 cm directly in front of the bird, usingcustom LabView software. Peristimulus time histograms (PSTHs;25 msec bin width) and median-filtered averaged membrane potentialswere computed off-line (see Dataanalysis).

    When possible, the intrinsic properties of an impaled cell were also studied, after characterization of the respiratory rhythmof the cell and its auditory responses to BOS playback. Hyperpolarizingresponses to negative current pulses (-.@t@cr, 百拇医药

    200 to -.@t@cr, 百拇医药

    400 pA, 1 sec duration,measured at steady state) were collected to estimate input resistance,and instantaneous and mean firing rates, as well as the latencyto the first spike, were calculated in response to positive currentpulses (+200 to +1000 pA, 1 sec duration). Cells were then filledwith neurobiotin using positive currents (+0.5 to +1 nA, 500 msecat 1Hz)..@t@cr, 百拇医药

    EMG signals were amplified (10,000×) and band-pass filtered (0.3-3 kHz) by an A-M Systems differential AC amplifier (A-M Systems,Everett, WA; model 1700). The signals were then digitized at 10kHz and stored on a PC hard drive. A BOS playback was considered"inspiration-linked" if it began during inspiration or within200 msec after the start of an inspiratory epoch, as determinedby visually inspecting the expiratory EMG (i.e., for periods ofexpiratory EMG inactivity). A BOS playback was considered to be"expiration linked" if it began during expiration or within 200msec after the onset of expiration, as determined by visuallyinspecting the expiratory EMG (i.e., for expiratory EMGactivity).

    HVc inactivation. To confirm that XIIts MNs received synaptic drive from telencephalic song nuclei, we recorded XIIts activityextracellularly in two urethane-anesthetized birds before, during,and after concentrated GABA [0.25 M in artificial CSF (ACSF)]infusion into HVc. A glass recording micropipette (tip outer diameter10-15 µm) filled with 1 M NaCl was lowered through the caudalcerebellum into XIIts, as identified by its depth from the cerebellarsurface (~4.4 mm), its distance from the midline (0.4 mm), andthe presence of a marked respiratory rhythm. Multiunit recordingswere then obtained while forward and reverse BOS were presentedas detailed above. After detection of BOS-evoked activity in XIIts,concentrated GABA was infused into the ipsilateral HVc using aPicospritzer (General Valve, Fairfield, NJ; each pulse was 25msec duration at 25 psi), starting with 10 pulses before songplayback and then 2 pulses during each interstimulus interval,sustained for a total of 5-15 stimulus iterations; XIIts activitywas monitored through the period of GABA application and untilforward BOS-evoked responses again became evident (~2-5 min).Similar size applications have been used to inactivate HVc inother studies conducted in this lab (R. Mooney, personalobservation).

    Retrograde labeling of XIIts MNs. To verify that the neurons that we recorded in the slice were syringeal and not lingualMNs [which lie rostroventral to XIIts MNs (Wild, 1993b)], we retrogradelylabeled XIIts MNs before in vitro recording sessions in a subsetof birds by injecting ventral syringeal muscles with 5% biotinylateddextran amine (BDA) (Molecular Probes, Eugene, OR; dissolved in0.025 M PBS) (Vicario and Nottebohm, 1988). With the bird underequithesin anesthesia (2 mg/kg, i.m.; 0.85 gm chloral hydrate,0.21 gm pentobarbitol, 0.42 gm MgSO₄, 2.2 ml 100% ethanol, 8.6ml propylene glycol brought to 20 ml final volume with dH₂O),a midline incision was made in the upper thorax to expose theinterclavicular air sac, which was then ruptured to reveal thesyrinx. The ventral syringeal muscles were then pressure injectedbilaterally with ~5 µl of BDA via a glass micropipette attachedto a Picospritzer, under visual guidance. The incision site wasthen sutured and coated with Neosporin. Birds were allowed torecover for transport of the BDA for 2-14 d before they were usedin anexperiment.

    Brain slices. These experiments used electrophysiological techniques that have been described extensively in previously publishedstudies (Mooney, 1992; Livingston and Mooney, 1997). Briefly,transverse brain slices from the medulla of adult (age 123-469post-hatch d) male zebra finches were cut at 400 µm and transferredto a holding chamber (room temperature). Intracellular recordingswere made using an interface-type chamber (30°C; Medical Systems).ACSF consisted of (in mM): 119 NaCl, 2.5 KCl, 1.3 MgCl₂, 2.5 CaCl₂,1 NaH₂PO₄, 26.2 NaHCO₃, 11 glucose, equilibrated with 95% O₂/5%CO₂. Equiosmolar sucrose was substituted for NaCl duringslicing.#?, 百拇医药

    In vitro electrophysiology. Sharp electrodes (borosilicate glass, BF100-50-10, Sutter Instrument) were pulled to yield a resistanceof 100-200 M"Omega "#?, 百拇医药

    when filled with 2 M K-acetate and 5% neurobiotin.A motorized microdrive (Newport Scientific, Irvine, CA; model860A) was used to lower electrodes into the nucleus, which wasvisible under epi-illumination as a circular structure situated~0.5 mm from the midline. Brief (~1 msec) capacitance overcompensationwas used to ring the electrode to achieve entry into the cell.An AxoClamp 2B intracellular amplifier (Axon Instruments) wasused in bridge mode to record intracellular membrane potentials,which were low-pass filtered at 3 kHz, digitized at 10 kHz, andstored on a PC hard drive. Only cells with resting potentialsnegative of -

    50 mV and overshooting spikes were used foranalysis.kj:u\y#, http://www.100md.com

    Hyperpolarizing responses to negative current pulses (-kj:u\y#, http://www.100md.com

    200 to -kj:u\y#, http://www.100md.com

    600 pA, measured during steady state) were collected to estimateinput resistance, and instantaneous and mean firing rates werecalculated in response to positive current pulses (+200-1000 pA,1 sec duration). Concentric bipolar stimulating electrodes (FredericHaer, Bowdoinham, ME) were placed in the lateral medulla, andsynaptic potentials in XIIts were evoked using brief (100 µsec)currents of 50-600 µA. In brain slices of the closed medulla,which often included the obvious commissura infima dorsal to thecentral canal, these electrodes were located in an area correspondingto the location of the lateral part of nucleus retroambigualis(RAm) (Wild, 1993a), which was discernible under epi-illuminationas an arc extending ventrolaterally from XIIts. In slices thatincluded the obex region, however, it was not possible to determinewhether the electrodes were located only in RAm because of theadditional presence at these levels of nucleus parambigualis (PAm),the source of inspiratory-related bulbospinal neurons that isrostrally continuous with RAm and also projects onto XIIts (Reinkeand Wild, 1998). The stimulating electrodes were moved dorsalor ventral to RAm to confirm the specificity of the stimulationlocus from which the response was evoked. To verify that the effectsof electrical stimulation were caused by the activation of cellbodies and not of fibers of passage, 10 mM glutamate was appliedto the site of effective stimulation via a puffer pipette, usingbrief (5 msec at 15 psi) pulses supplied by a Picospritzer. Oncedata collection was completed, cells were filled with neurobiotinusing positive currents (+0.5 to +1 nA, 500 msec at 1Hz).

    In vivo data analysis. The suprathreshold responsiveness (R_supra) of cells with spiking activity was calculated by R_supra= S_FR -(52t?md, http://www.100md.com

    B_FR, where S_FR and B_FR are the firing rates during eachstimulus presentation and during a 2.0 sec baseline period beforeeach stimulus presentation, respectively. To assess subthresholdresponsiveness in spiking and nonspiking cells, raw traces werefirst median filtered (each point was replaced by the median valueof the surrounding 50 points, equivalent to 5 msec at the 10 kHzsampling rate used here). Median filtering removed the actionpotential, which was typically ~1 msec in duration, yet did notdistort slower membrane potential movements (Jagadeesh et al.,1997, their Fig. 1). The subthreshold depolarizing responsiveness(R_Vm) of these cells was measured by R_Vm = S_area -(52t?md, http://www.100md.com

    B_area, whereS_area and B_area are the integrals of the positive-going deviationsin membrane potential (V_m) either during (i.e., S_area) or before(i.e., B_area) stimulus presentation relative to the mode membranepotential measured during the baseline period. That is, the totalpositive area during the baseline (measured from the mode) wassubtracted from the total positive area during the stimulus (measuredfrom the mode) [for examples of how these subthreshold valueswere measured, see Mooney (2000), his Fig. 9]. The mode membranepotential was calculated for the baseline data array with an automatedLabView routine and was used instead of the mean or median ofthe baseline data array because we observed that it gave the mostreliable measure of the central tendency of the baseline membranepotential. Similar calculations were made for the subthresholdhyperpolarizing area, but instead using the negative-going deviationsin membrane potential from the baseline mode value. The net subthresholdhyperpolarization was multiplied by -

    1, so that a net increasein subthreshold hyperpolarization relative to the baseline wouldbe represented by a negative number. It was possible for singlecells to respond to a stimulus with an increase in both negativeand positive area relative to baseline. Furthermore, strong hyperpolarizingresponses to a stimulus could yield negative values for positiveand negative area (e.g., when the baseline positive area was greaterthan positive area evoked by the stimulus). Average R_supra orR_Vm values were computed for 10-40 stimulus iterations. Significancewas determined with paired t tests comparing stimulus-evoked suprathreshold,subthreshold depolarizing, or subthreshold hyperpolarizing responsesto corresponding baselinemeasures.[o9k+, 百拇医药

    To compare suprathreshold and subthreshold responses, response strengths were expressed as z-scores. The suprathreshold z-score(Z_supra) is the difference between the average firing rate duringthe stimulus and during a 1.5 sec baseline period before stimuluspresentation, divided by the SD of this difference:

    "Z_supra=S&cjs1171;_FR−B&cjs1171;_FRVar(S_FR)+Var(B_FR)−2Covar(S_FR, B_FR),"'jp, 百拇医药

    where ^-S_FR is the mean firing rate during the stimulus and ^-B_FR is the mean firing rate during the baseline period, and thedenominator is the SD of S_FR -'jp, 百拇医药

    B_FR. For nonspiking cells and median-filteredspiking cells, the subthreshold z-score (Z_Vm) is given by thedifference between the average area during stimulus presentationand that during baseline, divided by the SD of this difference.The Z_Vm formula is the same as that for Z_supra, with substitutionsof area for FR, where ^-S_area is the mean deviation in V_m (from the baseline mode, calculatedseparately for negative or positive area, as stated above) duringsong presentation, and ^-B_area is the mean deviation in V_m during baseline; the denominatoris the SD of S_area -

    B_area.897d%|{, 百拇医药

    The selectivity of a neuron for forward over reverse BOS playback was measured using the psychophysical metric d' (Green andSwets, 1966):897d%|{, 百拇医药

    "d′_supra=2(R&cjs1171;_{FR_BOS}−R&cjs1171;_{FR_rev})&sfgr;²_BOS+&sfgr;²_rev"897d%|{, 百拇医药

    or897d%|{, 百拇医药

    "d′_{V_m}=2(R&cjs1171;_{area_BOS}−R&cjs1171;_{area_rev})&sfgr;²_BOS+&sfgr;²_rev ,"897d%|{, 百拇医药

    which estimates the discriminability between two stimuli. A difference in response to these two stimuli has been used previouslyas the criterion for auditory selectivity of neurons in HVc, aswell as in other song nuclei (Solis and Doupe, 1997; Theunissenand Doupe, 1998; Janata and Margoliash, 1999; Mooney, 2000; Rosenand Mooney, 2000). The d' value comparing the response to BOSrelative to reversed BOS is given by d'_supra, which representssuprathreshold responsiveness, and d'_Vm represents subthresholdresponsiveness. ^-R is the mean value of R (as described above), and "sigma "

    ² is its variance. This selectivity measure resembles a ratio measurebut accounts for both the mean and the variance of the responsesof a cell and can report negative values. A d' value >0.7 (or< -37c1v|, 百拇医药

    0.7, reflecting an excitatory bias toward reverse BOS) wasthe criterion used for terming a cell "selective"; this correspondedto p = 0.036 as measured by a paired t test comparing R_Vm or R_FRvalues with 20 presentations of BOS and reversed BOS. Note thatd' values for subthreshold responses (d'_Vm) were calculated separatelyfor positive and negative areas. Tests for statistical significanceare reported in the figure legends, except as noted inResults.37c1v|, 百拇医药

    In vivo and in vitro intrinsic data analysis. A software threshold event detector was used to measure instantaneous spikerates throughout the 1 sec period of positive current injection.Action potential half-height widths were measured from the shoulderof the spike, where the membrane potential described a sharp positiveinflection. The spike afterhyperpolarization (AHP) was measuredfrom the spike shoulder to the post-spike hyperpolarization trough.Similarly, afterdepolarizations (ADPs) were measured from thetrough of the spike AHP to the peak of the spike ADP. Restingpotential was determined by subtracting any DC offset observedafter electrode withdrawal. Input resistance measurements werecalculated by measuring the steady-state voltage caused by injectingsmall (-

    200 pA) hyperpolarizing current pulses. All values reportedare mean ± SEM; statistics and tests for significance are inResults.2, 百拇医药

    In vivo and in vitro histology. After an in vivo recording session the bird was deeply anesthetized with equithesin and transcardiallyperfused with 0.9% saline for 3 min, followed by 4% paraformaldehyde(PFA) in 25 mM sodium phosphate buffer for 30 min. The brain wasremoved and postfixed in 4% PFA with 30% sucrose overnight, blockedcoronally, and sectioned on a freezing microtome at 60 µm. Brainslices were immersion fixed in 4% PFA in 25 mM sodium phosphatebuffer and equilibrated in 30% sucrose overnight before sectioningon a freezing microtome at 60 µm. Both whole brain and brain slicesections were either processed using standard HRP-DAB reactiontechniques (Kittelberger and Mooney, 1999) or visualized usingAlexafluor 488 (Molecular Probes); sections were incubated overnightat 4°C in a 1:700 dilution of Alexafluor 488 and 0.4% Triton X-100in 0.025 M PBS, rinsed in PBS three times for 10 min each time,mounted, andcoverslipped.

    Resultsl, http://www.100md.com

    To directly assess the function of synaptic inputs that XIIts MNs receive from respiratory areas in the lateral medulla, wemade transverse brain slices through the level of the syringealportion of the hypoglossal motor nucleus in adult male zebra finches. We first characterized the intrinsic properties of morphologicallyidentified XIIts MNs during in vitro recording sessions and thenused electrical and chemical stimulation techniques to activatesynaptic inputs to XIIts from respiratory areas in the lateralmedulla. We then made in vivo intracellular recordings from XIItsMNs to measure synaptic activity during normal respiration andwhen telencephalic inputs to XIIts were activated in a naturalisticmanner by song playback.l, http://www.100md.com

    fig.ommittedl, http://www.100md.com

    Figure 1. These simplified diagrams emphasize the major vocal and respiratory pathways important for the production of learned vocalizations in the male zebra finch. At top is a sagittal view of the descending axons from the telencephalic song nucleus robustus archistriatalis (RA) to vocal and respiratory areas in the brainstem. At the bottom is a transverse brainstem section (made at the level of the dashed arrow in the sagittal view) resembling the orientation of the brain slices that we recorded from and showing the tracheosyringeal part of the hypoglossal nucleus (XIIts), which contains the motor neurons innervating the muscles of the avian song organ, or syrinx. XIIts receives ipsilateral and contralateral afferents from the nucleus retroambigualis (RAm), which also contains expiratory bulbospinal premotor neurons and is likely to be the source of expiratory-related activity detected in nXIIts and in the tracheosyringeal nerve. XIIts neurons also receive synaptic input from the nucleus parambigualis (data not shown), which contains inspiratory bulbospinal neurons, and from the ventrolateral parabrachial nucleus, the nucleus infra-olivaris superior, and the ventrolateral nucleus of the rostral medulla (data not shown) (Wild et al., 1990; Wild, 1993a, 1994). XIIts and RAm each receive afferents from the telencephalic song motor nucleus RA, as well as from the dorsomedial nucleus of the intercollicular region of the midbrain (data not shown) (Wild, 1993b; Wild et al., 1997). RA receives auditory and motor input from the song nucleus HVc (used here as a proper name); HVc and RA are essential to the production of learned vocalizations in songbirds. D, Dorsal; R, rostral; L, lateral.

    XIIts MN properties measured in vitro&&, http://www.100md.com

    In transverse slices through the caudal medulla, the hypoglossal nucleus is a distinct, round structure close to the centralcanal. But because the tracheosyringeal (XIIts) and lingual (XIIl)parts of the hypoglossal nucleus slightly overlap rostral to theobex, we conducted initial experiments to confirm that we wererecording from XIIts and not XIIl MNs. We first labeled tracheosyringealMNs by injecting retrograde tracers into the ventral syringealmuscles and then we intracellularly stained individual XIIts MNsin the slice. As expected of XIIts MNs, the impaled cells werewithin the field of retrogradely labeled cell bodies with extensive dendrites and unbranched axons exiting the nucleusventrally to enter the XIIts nerve root. Thereafter, we recordedfrom the part of the hypoglossal nucleus caudal to the obex, whichcontains only XIIts and not XIIl MNs (Wild, 1993a).&&, http://www.100md.com

    fig.ommitted&&, http://www.100md.com

     Morphological and intrinsic electrical features of XIIts MNs. A, Intracellular staining of an XIIts MN shows dendrites extending into regions surrounding nXIIts and an axon that travels ventrally along the midline toward the XIIth nerve rootlet. Motor neurons (gray polygons) in the rostral portion of XIIts were labeled by injection of retrograde tracer into the ventral syringeal muscle several days before intracellular filling in a brain slice preparation. D, Dorsal; L, lateral. B, In vitro, XIIts MNs generated highly regular trains of action potentials in response to positive currents. Membrane potential responses of an XIIts MN to positive and negative injected currents (±200 pA; the pulse duration is shown below the superimposed voltage traces) passed through the recording electrode are shown from an in vitro intracellular recording made in a brain slice. The inset trace highlights the spike afterdepolarization (ADP) characteristic of XIIts MNs. C, An in vivo intracellular membrane potential recorded from a XIIts MN shows that in response to a +200 pA current injected through the recording electrode, the cell generates a train of action potentials similar to those seen in vitro, but with action potential suppression, likely to be occurring during the inspiratory phase of respiration (arrow) (and Results). Note that subthreshold membrane potential movement during this inspiratory phase consists of a gradual rather than abrupt hyperpolarization. D, The average firing frequencies (in hertz; in vitro, left; in vivo, right) are plotted as a function of the amplitude of the positive current injected through the recording electrode for populations of XIIts MNs (in vitro, 40 cells; in vivo, 5 cells). The average firing frequency as a function of injected current in vitro and in vivo was highly linear between 0 and +0.6 nA. E, Instantaneous action potential frequency plots (in vitro, left; in vivo, right; averages from same cells as in D).

    The XIIts neurons that we recorded from displayed remarkable homogeneity in their intrinsic properties. In vitro, XIIts MNshad average resting potentials of -ax8@}, 百拇医药

    64 ± 1 mV (mean ± SEM) andaverage input resistances of 49 ± 3 M"Omega "ax8@}, 百拇医药

    in vitro. AlthoughXIIts MNs recorded in vitro showed no evidence of rhythmic actionpotential discharge like the rhythmic respiratory activity thatthey display in vivo (see below), a subset of cells recorded invitro exhibited tonic action potential discharge (22 of 40 cells;~24 Hz). Positive currents passed through the recording electrode-elicitedaction potential trains from XIIts MNs , the mean dischargerates of which increased in a linear manner with injected positivecurrents, up to an amplitude of +1 nA in vitro . Theinstantaneous frequency of these evoked action potential trainsdropped over the first few interspike intervals and then remainedfairly constant over the remainder of the injected pulse . Spike AHPs and ADPs (noted as a positive peak immediatelyafter spike) were observed in all cells (40 of 40 cells), andanomalous rectification, evinced as a sag in the hyperpolarizingresponse to a negative current pulse, was seen in a subset ofcells (14 of 40 cells) .

    fig.ommitted3p, http://www.100md.com

    Intrinsic properties of XIIts MNs in vivo and in vitro3p, http://www.100md.com

    3p, http://www.100md.com

    Synaptic inputs from lateral medullary respiratory centers to XIIts studied in vitro3p, http://www.100md.com

    To probe directly the synaptic connections made by respiratory centers located in the lateral medulla onto XIIts MNs, we madeintracellular recordings from XIIts MNs in brain slices and appliedfocal electrical stimulation to the region containing either theipsilateral or contralateral RAm depicts a summary schematicof stimulation sites). Previous studies showed that RAm consistsof a narrow band of cells extending laterally from XIIts, swellingslightly in extent as it approaches the lateral border of themedulla (see also Wild, 1993a). In practice, we foundthat the stimulating electrode evoked synaptic responses in XIItsfrom very restricted sites in the lateral medulla. These "hotspots" approximated the diameter of the stimulating electrode(0.5 mm) and were located in the region known to include RAm.

    fig.ommittedpw, 百拇医药

     A schematic summarizing the types and frequencies of synaptic and antidromic responses evoked in XIIts MNs after electrical stimulation at different sites (marked by asterisks) within the transverse brain slice preparation of the caudal medulla. A, Stimulation in ipsilateral RAm predominantly evoked IPSPs and rarely evoked EPSPs. B, Contralateral RAm stimulation evoked IPSPs and EPSPs from a small fraction of the cells tested. C, D, Stimulation in the XIIts nerve root evoked antidromic spikes (ipsilateral stimulation) and IPSPs (contralateral stimulation) in XIIts MNs. The numbers in parentheses refer to the number of cells showing the response illustrated by the accompanying trace of the total number of cells tested. D, Dorsal; L, lateral.pw, 百拇医药

    Ipsilateral stimulation of RAm evoked IPSPs in almost all XIIts MNs tested top trace) (136 of 145 cells; 40 birds),whereas it evoked EPSPs in a small fraction of cells tested (9of 145 cells; 40 birds) ( bottom trace). In a smallernumber of cells, we also examined whether the lateral medullaprovided functional synaptic input to the contralateral XIIts.Indeed, contralateral RAm stimulation led to detectable PSPs inalmost half the cells tested (8 of 18 cells; nine birds); these consisted of both IPSPs (4 of 18 cells, three birds)and EPSPs (4 of 18 cells; three birds). Stimulation of lateralmedullary sites either just dorsal or ventral to the area of RAm(i.e., movement of one diameter of the stimulating electrode awayfrom RAm) did not evoke PSPs in XIItsMNs.

    Responses in XIIts MNs were also detected after electrical stimulation of both the ipsilateral and contralateral hypoglossalrootlets . Although direct stimulation of the XIItsnucleus itself was not attempted, it is probable that the stimulatingelectrode selectively activated ipsilateral XIIts MNs via antidromicpropagation of the spike via the nerve root. Consistent with thisidea, stimulation of the ipsilateral hypoglossal rootlet evokedantidromic spikes in half of the XIIts MNs that we tested (9 of18 cells; three birds). Unexpectedly (see Discussion), stimulationof the ipsilateral and contralateral hypoglossal nerve root couldalso evoke synaptic responses in XIIts. Specifically, stimulationof the ipsilateral hypoglossal rootlet evoked IPSPs in 7 of 18cells in three birds, whereas stimulation of the contralateralhypoglossal rootlet evoked IPSPs in a majority of cells tested(20 of 29 cells; four birds) and an EPSP in one cell (data notshown). In the case of responses evoked by contralateral nerveroot stimulation, we assume that XIIts MNs ipsilateral to thestimulation site were synaptically interposed between the stimulationand recording sites, because XIIts axons project only ipsilaterally(Wild, 1997) (seeDiscussion).

    Synaptic pharmacology60y!e, 百拇医药

    The mean reversal potential of IPSPs (-60y!e, 百拇医药

    87 ± 6 mV; n = 7 cells from 5 birds) evoked in XIIts MNs by RAM stimulation is consistentwith either glycine or GABA receptor mediated inhibition. To bettercharacterize inhibitory synaptic inputs from the lateral medullaonto XIIts MNs, we used a puffer pipette to apply focally GABA-and glycine-receptor blockers [100 µM bicuculline methiodide (BMI)and strychnine dissolved in ACSF] to the XIIts intracellular recordingsite while electrically stimulating synaptic inputs from the ipsilateralRAm. These drugs applied together abolished the IPSP in all cellsthat we tested (10 cells; eight birds), and in all such cases,rather than simply failing to evoke any response, electrical stimulationthen elicited an EPSP (mean IPSP amplitude,-60y!e, 百拇医药

    4.7 ± 1 mV; mean EPSP amplitude, +4.1 ± 1 mV; t₍₉₎ = -60y!e, 百拇医药

    6.26; p< .001). In an attempt to characterize more precisely the natureof synaptic inhibition evoked in XIIts by ipsilateral RAm stimulation,we also bath applied 100 µM strychnine in another group of XIItsMNs . In all 16 cells (nine birds), IPSPs were abolishedafter strychnine application alone, and EPSPs were again unmasked (mean IPSP amplitude, -

    3.5 ± 0.4 mV; mean EPSP amplitude,+4.8 ± 0.7 mV; t₍₁₅₎ = -^icdag[, http://www.100md.com

    8.51; p < 0.001). Although strychninecompletely blocked RAm-evoked IPSPs in XIIts MNs, it did not alterXIIts MN membrane potential or input resistance Theseresults suggest that synaptic inhibition evoked in XIIts by ipsilateralRAm stimulation is mediated primarily via glycine receptors, althoughthe additional possibility that GABA receptor-mediated inhibitionis present but masked by strong excitation (i.e., in the presenceof strychnine) cannot be ruled out at this stage. Finally, wewere also interested in knowing whether the onset latencies differedbetween IPSPs and EPSPs evoked in the same cells, possibly reflectingmonosynaptic versus polysynaptic transmission. Similar PSP onsetlatencies were noted before and after strychnine treatment (IPSPlatency, 2.2 ± 0.2 msec; EPSP latency, 1.8 ± 0.2 msec; n = 16cells; p = 0.13; t₍₁₅₎ = 1.61), suggesting that both inhibitoryand excitatory responses evoked in XIIts by RAm stimulation aremediated by monosynaptic pathways.

    fig.ommitted54na, http://www.100md.com

     Electrical stimulation in RAm evokes synaptic inhibition in XIIts MNs mediated predominantly by glycine receptors. A, IPSPs evoked in XIIts MNs by ispilateral RAm stimulation were abolished by combined application of GABA_A and glycine receptor blockers (BMI and strychnine; see Materials and Methods for details). This treatment reversibly abolished the IPSPs elicited in XIIts MNs and unmasked EPSPs. An asterisk marks stimulation time. B, Scatterplots of PSP amplitude before (control) and immediately after treatment with strychnine and BMI (left) or strychnine alone (right).54na, http://www.100md.com

    fig.ommitted54na, http://www.100md.com

    Synaptic properties of XIIts MNs in vitro54na, http://www.100md.com

    54na, http://www.100md.com

    Interestingly, in the presence of either GABA and glycine receptor antagonists or glycine receptor antagonists alone, stimulationin RAm could evoke prolonged excitatory responses in XIIts inthe form of action potential trains or long-lasting subthresholddepolarizations . The amplitude and duration of theseexcitatory responses were highly dependent on the postsynapticmembrane potential, and they diminished in amplitude and becamehighly phasic when the impaled cell was held in a hyperpolarizedstate via tonic current injection (controlmean EPSP amplitude, 4.4 ± 0.8 mV at a mean V_m of -

    63 ± 1.8 mV;hyperpolarized mean EPSP amplitude, 2.9 ± 0.6 mV at a mean V_mof -n[{zm), 百拇医药

    82.9 ± 3.7 mV; t₍₇₎ = 3.46; p = 0.01; mean net negative DCinject = -n[{zm), 百拇医药

    0.6 ± 0.09 nA; n = 8 cells from 5 birds).n[{zm), 百拇医药

    fig.ommittedn[{zm), 百拇医药

     In the presence of glycine receptor blockers, electrical stimulation in ipsilateral RAm evoked EPSPs in XIIts MNs mediated in part by NMDA receptors and which were sufficient to translate single EPSPs into a sustained action potential discharge. A, A single EPSP could trigger sustained trains of action potentials at the actual resting potential of the cell (actual Vm) but was rendered highly phasic and entirely subthreshold when the impaled XIIts MN was slightly hyperpolarized via tonic negative current injection through the recording electrode (more negative Vm). B, The slow portion of the EPSP evoked by RAm stimulation in brain slices bathed in strychnine had the voltage-dependence characteristic of NMDA receptor-mediated transmission and was strongly attenuated by hyperpolarization of the postsynaptic XIIts membrane. The EPSP evoked by RAm stimulation is displayed at the actual resting potential of the cell (topmost trace; actual Vm) or at a slightly more negative membrane potential (bottom trace; more negative Vm) achieved by passing tonic current through the recording electrode. The EPSP triggered a train of action potentials at the more positive membrane potential. Subsequent treatment with the NMDA receptor blocker D-APV reduced the EPSP in a manner resembling postsynaptic hyperpolarization, localizing the NMDA receptors to the impaled cell. C, The slow portion of the EPSP was blocked reversibly by applying NMDA receptor antagonists to XIIts. EPSPs that were collected before and during application of the NMDA receptor antagonist D-APV to XIIts are shown superimposed (see Materials and Methods). These results suggest that NMDA receptors on the XIIts MN are activated by lateral medullary inputs. Raw traces are shown in A and B, and averages of three to six traces are shown in C. Stim, Stimulation time.

    The voltage dependence of EPSPs evoked in XIIts is suggestive of postsynaptic NMDA receptor activation on the impaled motorneuron, an idea that we confirmed by blocking the slow componentof the EPSP with the NMDA receptor blocker D-amino-5-phosphopentanoicacid (APV; 100 µM). In the presence of bath-applied strychnine,subsequent puffer pipette application of APV to XIIts significantlyreduced the overall amplitude of the evoked EPSP (mean EPSP amplitude before APV, 5.2 ± 0.8 mV; meanEPSP amplitude in APV, 3.5 ± 0.7 mV; t₍₇₎ = 5.26; p = 0.0012;n = 8 cells from 7 birds). These effects on EPSP amplitude werenot accompanied by significant changes in membrane potential. Suitably long recordings were obtained to wash out the APVeffect in four of these cells . The mean EPSP amplitudesbefore APV (4.7 ± 1.1 mV) and after drug washout (5.3 ± 0.8 mV)did not differ significantly from one another (t₍₃₎ = -:wwhh, 百拇医药

    0.68; p= 0.55), whereas both were significantly larger than the meanEPSP amplitude measured in the presence of APV (2.7 ± 0.7 mV;t₍₃₎ = 3.78, p = 0.03 and t₍₃₎ = -

    4.99, p = 0.01, respectively).Ultimately, the similar effects of postsynaptic hyperpolarizationand APV treatment on the slow component of the EPSPsuggest that axons arising from or traveling through the lateralmedulla activate NMDA receptors on XIIts MNs. Presumably, thesynaptic response evoked in the presence of D-APV was mediatedby non-NMDA glutamate receptor types.)7, 百拇医药

    fig.ommitted)7, 百拇医药

    Scatterplots of EPSP amplitude before (control) and with the impaled cell held in a hyperpolarized state (left; more negative V_m) or treated with D-APV (right; APV). With either treatment, EPSPs were attenuated to a similar degree .)7, 百拇医药

    To determine whether PSPs evoked in XIIts by electrical stimulation of the lateral medulla were caused by synaptic inputsderived from cell bodies in RAm or instead from fibers of passagearising from more rostral sources of input to XIIts (Wild, 1994,1997), we focally applied glutamate (10 mM dissolved in ACSF)at the electrical stimulation site in ipsilateral RAm. As withthe electrical stimulation, synaptic responses from XIIts MNswere evoked by glutamate application from hot spots typicallydirectly under the simulating electrode. In 12 cells from sixbirds, glutamate application elicited membrane potential changesin the impaled XIIts MN, and the initial component of the chemicallyevoked response was always of the same sign as that of the synapticresponse evoked by electrical stimulation at the same site (hyperpolarizing responses were seen in 10 cells, and depolarizingresponses were seen in 2 others). Furthermore, as with electricalstimulation, we found in four other cells that focal glutamateapplication that initially evoked hyperpolarizing responses fromXIIts MNs in normal ACSF subsequently evoked depolarizing, excitatoryresponses after bath application of strychnine (n = 4cells). Taken together, these results suggest that different populationsof neurons located within the lateral medulla supply XIIts MNswith inhibitory and excitatory synaptic input.

    fig.ommitted-xun, 百拇医药

     EPSPs and IPSPs evoked in XIIts MNs from lateral medullary stimulation are attributable to cell bodies local to RAm. In control ACSF (top), electrical stimulation and glutamate application in the same spot in the lateral medulla evoked similar inhibitory responses in this XIIts MN. After strychnine application (bottom), which abolished the inhibitory responses, the same stimulation protocol evoked depolarizing, excitatory responses. An arrow marks the time of electrical (left) or chemical (glutamate; right) stimulation in each case. Traces shown are averages of three to six individual records.-xun, 百拇医药

    In vivo properties of XIIts MNs-xun, 百拇医药

    The brain slice recordings that we made suggest that a dominant synaptic input to XIIts from respiratory areas in the lateralmedulla activates glycine receptor-mediated inhibition but thatthis inhibition often masks an underlying excitatory component.Because previous extracellular recordings in XIIts and from thetracheosyringeal nerve made in vivo detected expiratory linkedfiring and left the synaptic basis of such activity unresolved,we were interested in relating in vitro to in vivo synaptic functionin XIIts. Therefore, we made additional intracellular recordingsfrom XIIts MNs in vivo, assessing their intrinsic properties,the synaptic events underlying their respiratory activity, andtheir modulation by synaptic inputs from thetelencephalon.

    In vivo XIIts MN intrinsic properties+, http://www.100md.com

    The intrinsic properties of XIIts MNs were remarkably similar to those that we measured in brain slices. In vivo, XIIts MNshad average resting potentials of -+, http://www.100md.com

    60 ± 4 mV (mean ± SEM; n =6 cells from 5 birds) and average input resistances of 49 ± 11M"Omega "+, http://www.100md.com

    in vivo (n = 5 cells from 5 birds) and producedspontaneous, rhythmic action potential trains entrained to theexpiratory phase of respiration (see below). Positive currentpulses injected through the recording electrode also evoked actionpotential trains with mean and instantaneous firing frequenciesresembling those seen in XIIts MNs recorded in brain slices . Unlike XIIts MNs recorded in vitro, brief interruptionsin action potential discharge were occasionally observed in vivoduring the injection of small positive currents ,possibly reflecting inspiratory-linked suppression of XIIts MNactivity. AHPs and ADPs were observed in all six cells testedwith positive currents (six of six cells from five birds), andanomalous rectification was seen in a subset of cells that wereexamined (three of six cells in vivo) .

    In vivo characterization of XIIts MN respiratory activityg, 百拇医药

    To examine the synaptic events underlying respiratory activity in XIIts MNs, we made intracellular recordings from them whilesimultaneously monitoring respiration using abdominal EMGs. Acomparison of intracellular and EMG records revealed a highlyregular pattern of action potential discharge in XIIts MNs thatwas predominantly in phase with the activity in abdominal expiratorymuscles (12 cells from two birds). Firing persisted throughoutexpiration and ceased at the offset of the expiratory EMG (i.e.,during inspiration).g, 百拇医药

    fig.ommittedg, 百拇医药

     XIIts motor neurons display a pronounced respiratory rhythm. An in vivo intracellular recording from an XIIts MN was used to monitor its membrane potential, whereas a simultaneous EMG was obtained from abdominal expiratory muscles to measure respiratory activity. XIIts MN firing was always in phase with the expiratory EMG.g, 百拇医药

    Although the initial inspection of intracellular traces showed that XIIts MNs were active during expiration and quiescentduring inspiration, the synaptic events underlying the respiratoryrhythm were not readily apparent because of sustained action potentialdischarge during expiration. To detect underlying synaptic events,we varied the membrane potential of XIIts MNs by injecting depolarizingor hyperpolarizing DC current through the recording electrode(approximately ±1 nA). When XIIts MNs were hyperpolarized belowtheir normal resting potential, their pattern of activity changedmarkedly; in this more negative state, XIIts MNs produced veryphasic bursts of only a few action potentials at the onset ofexpiration . This pattern of activity in a hyperpolarizedstate was suggestive of a strong excitatory input onto XIIts MNsat expiration onset. When XIIts MNs were held at or slightly abovetheir actual resting potential, they produced trains of actionpotentials that began in phase with the onset of expiration andterminated with expiratory EMG offset. However, in neither hyperpolarizednor depolarized states were we able to detect inhibitory synapticevents underlying expiration offset.

    fig.ommitted3, http://www.100md.com

    Membrane potential manipulations reveal phasic excitation at expiratory EMG onset. An in vivo intracellular recording (mV) from an XIIts MN and a simultaneous abdominal muscle EMG (EMG) were used to measure the nature of respiratory activity in XIIts. During these recordings, the XIIts MN membrane potential was either slightly depolarized (top) or moderately or more strongly hyperpolarized (middle and bottom) by injecting positive or negative currents through the recording electrode. When slightly depolarized from its resting membrane potential value with positive current (+0.5 nA, top), the neuron showed only gradual membrane hyperpolarization (but abrupt firing rate suppression) during the inspiratory phase. When moderately or more substantially hyperpolarized from its resting membrane potential with tonic negative current passed through the recording electrode (-3, http://www.100md.com

    1.25 nA, middle; -3, http://www.100md.com

    1.5 nA, bottom), the neuron displayed subthreshold excitation occurring abruptly at the onset of expiration. No membrane potential movements were noted at the offset of expiratory EMG activity.

    In vivo responses of XIIts MNs to song playback?c/, 百拇医药

    In addition to receiving respiratory-related inputs from the lateral medulla, XIIts MNs are the target of direct synapticinput from the telencephalic song nucleus RA. In urethane-anesthetizedzebra finches, auditory presentation of the BOS potently excitestelencephalic song nuclei, including RA (Margoliash and Konishi,1985; Doupe and Konishi, 1991; Vicario and Yohay, 1993). Suchplayback also activates XIIts neurons (Williams and Nottebohm,1985), likely via the projections that they receive from RA. Furthermore,a recent study showed the BOS-evoked activity of RA neurons resemblestheir activity during singing (Dave and Margoliash, 2000), suggestingthat playback also triggers behaviorally relevant activity patternsinXIIts.?c/, 百拇医药

    To confirm that the song-evoked responses observed in XIIts were derived from the telencephalic vocal control system, we mademultiunit extracellular recordings of XIIts activity in responseto BOS playback and then reversibly inactivated HVc, the auditoryafferent of RA (Doupe and Konishi, 1991; Mooney, 1992; Vicarioand Yohay, 1993). Before GABA application (0.25 M in ACSF) toHVc, forward BOS presentation evoked action potential dischargein XIIts MNs; GABA application to HVc reversibly abolished theseresponses (three sites in two birds).

    fig.ommittedg;-+, 百拇医药

     The BOS playback-evoked responses in XIIts depend on activity in the telencephalic song nucleus HVc. A multiunit extracellular recording was made in XIIts, and baseline responses to BOS playback (shown as an oscillogram at the bottom) were collected [top, Pre-inactivation; 10 stimulus iterations; responses are shown as action potential PSTHs (XIIts spikes/bin)]. The telencephalic song nucleus HVc was then inactivated by injecting it with concentrated GABA (0.25 M in 0.9% saline) ejected through a puffer pipette placed stereotactically in the nucleus. BOS playback failed to excite XIIts MNs when HVc was inactivated with GABA (middle, GABA into HVc). Reponses to BOS playback could again be detected within several minutes after GABA application to HVc (bottom, Post-inactivation). Response strengths (RS) and significance levels are given for each condition.g;-+, 百拇医药

    Although the inactivation experiments indicate that inputs from the telencephalon are necessary to drive song-evoked firingin XIIts, they do not rule out the existence of other auditoryinputs that are insufficient on their own to drive XIIts MNs tospike threshold. Temporal sensitivity to the BOS, as manifestedas a strong bias in response strength to forward over reverseBOS playback, is one feature that distinguishes auditory responsesin RA from many other auditory areas. When presented with thesetwo stimuli, all XIIts MNs were excited significantly by forwardbut not reverse BOS playback (8 intracellular recordings;10 extracellular multiunit recordings; mean response strengthto forward BOS: intracellular = 29.45; extracellular = 5.56) suprathresholdresponses; no significant excitatory responses were evoked byreverse BOS). Firing rate responses to the forward and reverseBOS recorded either intracellularly or extracellularly showedan overwhelming bias toward the forward stimulus [meanBOS Z-score_intra = 4.0 ± 0.7; mean reverse BOS Z-score_intra =-

    0.48 ± 0.11; mean BOS Z-score_extra = 1.1 ± 0.2; mean reverseBOS Z-score_extra = -qy8%, 百拇医药

    0.04 ± 0.1; paired t tests; BOS versus reverse(REV) BOS, for intracellular (t₍₇₎ = 5.87, p < 0.001) and extracellular(t₍₉₎ = 5.55, p < 0.001) suprathreshold responses]. To inspectunderlying synaptic events, we tonically hyperpolarized impaledXIIts MNs, accentuating subthreshold depolarizations evoked byforward BOS playback [mean BOS Z-score_intra = 2.21± 0.67; mean reverse BOS Z-score_intra = -qy8%, 百拇医药

    0.06 ± 0.20; paired ttest; BOS versus REV BOS, for intracellular subthreshold responses(t₍₆₎ = 4.154, p = 0.006)]. Although reverse BOS playback elicitedneither subthreshold nor suprathreshold excitatory responses n = 5 cells), it did suppress firing in one cell. A directcomparison of selectivity for the forward over reverse BOS stimulus,quantified as a d' value, indicated that, as a population, XIItsMNs display both action potential and subthreshold responses highlyselective for the forward song (suprathreshold: meanBOS d'_intra = 7.05 ± 1.10, mean BOS d'_extra = 1.79 ± 0.30; subthreshold:mean d'_intra = 3.97 ± 0.97). Along with the effects of HVc inactivation,the highly selective responses seen in XIIts suggest that RA islikely to be its sole source of auditory input.

    fig.ommitted/$8&i], 百拇医药

     XIIts MNs show subthreshold and suprathreshold responses that are highly selective for forward over reverse BOS playback. A, Z-scores of forward (x-axis) and reverse BOS (REV BOS) (y-axis) evoked suprathreshold responses (from extracellular and intracellular recordings; filled circles and filled squares, respectively) and subthreshold responses (from intracellular recordings; open squares) show an overwhelming bias to the forward stimulus, indicative of strong temporal sensitivity to the BOS. All forward BOS responses were highly significant; an arrow notes the only significant reverse BOS response, which involved firing rate suppression. B, Within-cell comparisons of subthreshold versus suprathreshold d' values obtained from intracellular records indicate that XIIts MNs are more selective for forward over reverse BOS at a suprathreshold than at the subthreshold level (dashed lines indicate the lower bounds for selective BOS responses)./$8&i], 百拇医药

    fig.ommitted/$8&i], 百拇医药

     Forward and not reverse playback of the bird's own song (BOS) strongly excites XIIts MNs. An in vivo intracellular recording from an XIIts MN reveals its membrane potential responses [XIIts Vm (mV)] to playback of the BOS and reverse BOS (REV BOS); a corresponding expiratory EMG is shown below each intracellular trace. Strong excitatory suprathreshold responses accompanied by subthreshold depolarizations were detected in response to forward, but not reverse, BOS playback. Unlike XIIts activity in the absence of song playback, hyperpolarizing events can be seen (top trace, marked by an arrow at the onset of the BOS-evoked response), and strong excitation could occur out of phase with the expiratory EMG. The absence of subthreshold responses to reverse BOS in XIIts indicates that its auditory afferent does not generate action potentials to this stimulus. Such behavior is characteristic of neurons in RA, the telencephalic afferent of XIIts, consistent with the idea that RA is the source of XIIts auditory responses.

    fig.ommitted?, 百拇医药

     Excitatory BOS-evoked responses in XIIts MNs could be preceded by subthreshold hyperpolarizations, suggestive of auditory-evoked inhibition. A, An in vivo intracellular recording from an XIIts MN revealed that strong excitatory responses were evoked by BOS playback (action potential responses to the entire BOS playback are shown as a PSTH at the top). An expanded region near BOS onset (shown as an oscillogram at the bottom) shows the PSTH and the averaged median-filtered membrane potential record aligned to the stimulus. Note that a sharp hyperpolarization precedes the initial volley of action potentials. This feature could be mediated by inhibition onto the XIIts MN driven by RA axons that innervate lateral medullary areas including RAm and PAm. B, Individual, median-filtered membrane potential traces from three cells [including the cell shown in A (cell 1)] show that BOS-evoked hyperpolarizations exceeded the negativities associated with the resting respiratory rhythm (marked by a horizontal line), even when the cell was held at relatively hyperpolarized potentials with tonic negative current (cell 1 and cell 2; "resting" membrane potential in millivolts is indicated to the left of each trace). Song onset marks the beginning of the BOS playback.

    To characterize further the nature of telencephalic inputs to XIIts, including their possible interaction with respiratoryinputs, we recorded BOS-evoked activity either extracellularlyor intracellularly from XIIts MNs while monitoring the respiratorycycle via abdominal expiratory EMGs . Although the neteffect of BOS-evoked telencephalic drive to XIIts is clearly excitatory,as evinced in both extracellular and intracellular records, intracellularrecords also revealed that BOS-evoked excitation could be precededby a brief (~50 msec) hyperpolarizing movement of the membranepotential (five cells from one bird). Such hyperpolarizing eventswere observed both in individual raw membrane potential recordsand in three of the five cells in the averaged median filteredmembrane potential traces and were characterizedby sharp onsets and negativities below membrane potential valuesbefore the stimulus .:\, 百拇医药

    The hyperpolarizing events that we observed are consistent with the idea that, in addition to directly exciting XIIts, RAalso excites inhibitory cells in RAm that innervate XIIts. Moredirect evidence of the influence of RA on RAm was noted by monitoringabdominal muscle EMGs during song playback: in two birds, forwardbut not reverse BOS playback augmented the expiratory EMG . Another apparent and possibly related effect of forward andreverse BOS playback on RAm was to entrain expiratory activity:PSTHs of abdominal expiratory EMG activity constructed from multiplestimulus iterations revealed pronounced troughs and peaks deviatingfrom the prestimulus baseline(n = 2 birds).

    fig.ommittedhw|r+v, 百拇医药

     Changes in XIIts MN input impedance during BOS playback and during subsequent respiratory entrainment. Forward (bottom left) and reverse BOS (REV BOS) (bottom right) playback-evoked vocal and respiratory activity, as revealed by simultaneous abdominal expiratory EMGs (top) and intracellular recordings from an XIIts neuron [action potential PSTH (XIIts spikes) and median-filtered average membrane potential (XIIts Vhw|r+v, 百拇医药

    m)]. In the lower of the two median filtered traces, the XIIts MN was injected with brief (20 msec) hyperpolarizing (-hw|r+v, 百拇医药

    0.5 nA) currents through the recording electrode at 8 Hz to monitor postsynaptic impedance changes indicative of changes in synaptic conductances. Forward BOS strongly excited the XIIts neuron, resulting in marked impedance decreases (open arrows), consistent with elevated excitatory synaptic drive during song playback. Note that expiratory activity increased just before the augmentation in XIIts MN (enhanced EMG activity is marked by a solid arrow). Inspiration, reflected as troughs in the EMG, consistently followed forward BOS playback in this case. Such respiratory entrainment also occurred in response to reverse BOS playback, although this stimulus did not excite the XIIts neuron (note different y-axis scales for the forward vs reverse BOS-evoked XIIts PSTHs). Postsynaptic impedance decreases, measured as decrements in the amplitude of the DC-evoked hyperpolarizations, were not detected during such entrained inspiration, although slight impedance decreases were noted during subsequent expiratory phases (marked by open arrows, aligned to XIIts spiking and EMGs with closed arrows). These results are consistent with the idea that the XIIts respiratory rhythm derives primarily or solely from expiratory-driven excitation. Seventy iterations each of forward and reverse BOS playback were used to construct the PSTHs of XIIts MN and expiratory EMG activity, whereas 20 iterations were used to generate each of the two median filtered V_m values (i.e., current pulses were not injected through the recording electrode on every trial).

    We also assessed whether the response of a cell to BOS differed if the playback immediately followed an expiratory event,as measured by heightened EMG activity, or instead by a periodof muscular inactivity, presumed to reflect inspiration. In fourof five cells, response strength was higher when expiration immediatelypreceded playback, and the mean response strength was slightlyhigher in the "expiratory" versus "inspiratory" group, althoughthis effect did not achieve significance (RS_BOSexp = 29.6 ± 7.0vs RS_BOSinsp = 23.9 ± 9.3; t = -|^2]q\j, 百拇医药

    1.9; df = 4; p = 0.13).|^2]q\j, 百拇医药

    To assess relative levels of synaptic activity in XIIts during BOS-evoked excitation and subsequent respiratory entrainment,we applied brief negative current pulses (-|^2]q\j, 百拇医药

    0.5 nA) through therecording electrode before, during, and after playback. The resultantvoltage deflections diminished transiently near the peak of theforward BOS-evoked depolarizations, consistent with the idea thatforward BOS playback augments excitatory synaptic drive to XIItsMNs (relative impedance change -

    8.1 ± 1.9 M"Omega "#'lmx, 百拇医药

    , a 31% decrease;n = 3 cells). Furthermore, in almost all (four of five) of thecells that we tested, decreases in postsynaptic impedance weredetected at the onset of the entrained expiratory onset but notduring inspiration (relative impedance change -#'lmx, 百拇医药

    2.4 ± 0.3 M"Omega "#'lmx, 百拇医药

    , a10% decrease; n = 4 cells). The impedance of one cell decreasedat the trough of the entrained expiratory EMG (i.e., at inspiration).These impedance changes suggest that synaptic activity in XIItsincreases prominently during BOS playback and expiration but notduringinspiration.#'lmx, 百拇医药

    Discussion#'lmx, 百拇医药

    In both anesthetized and awake nonsinging zebra finches, XIIts MNs fire action potentials predominantly in phase with expiration,as measured extracellularly in the nucleus or nerve or by syringealEMGs (Manogue and Paton, 1982; Williams and Nottebohm, 1985 Vicario,1991a) and confirmed here intracellularly. Although previous studiesleft open whether this rhythm results from expiratory-linked excitationor inspiratory-linked inhibition, or both, we observed that themajor component of this rhythm involves expiratory-linked excitation.Hyperpolarization of the XIIts MN revealed phasic subthresholddepolarizations locked to expiratory onset and an absence of membranepotential movement at expiratory offset. Furthermore, in casesshowing expiratory EMG entrainment to song playback, postsynapticimpedance decreases (likely reflecting enhanced synaptic activity)commonly were detected in XIIts MNs during the subsequent expiratoryphase but not during inspiration. Although we cannot exclude morecryptic forms of inspiratory-linked inhibition in XIIts, theseresults emphasize that expiratory-linked excitation dominatesthe XIIts respiratory rhythm. During singing, expiratory excitationof XIIts could serve as an "and" gate (Manogue and Paton, 1982),at least for MNs involved with syringeal adduction (Goller andSuthers, 1996a), thereby precisely coordinating expiration andvocal output (Hartley and Suthers, 1990).

    In direct contrast to a model of purely expiratory-driven XIIts excitation, however, we found in vitro that electrical stimulationin a lateral medullary area corresponding to RAm evoked IPSPsfrom the majority of XIIts MNs. These IPSPs were mediated primarilyby glycine receptors and reversed at relatively negative potentials,consistent with a potassium current. Moreover, glutamate applicationto RAm also evoked IPSPs, suggesting that they were mediated byRAm neurons and not by fibers passing through RAm to XIIts. Additionalrespiratory-related inputs to XIIts not characterized here mightarise from more rostral brainstem sources, including the inspiratory-relatedPAm (Reinke and Wild, 1998) and the ventrolateral parabrachialpontine nucleus (Wild et al., 1990).u;, http://www.100md.com

    Despite the strong inhibitory influence of RAm on XIIts observed in the slice, in vitro recordings also point to RAm as thelikely source of expiratory-linked excitation to XIIts. When inhibitionto XIIts was blocked, electrical and chemical stimulation of RAmroutinely evoked EPSPs in XIIts MNs. These results suggest thattwo functionally distinct RAm neuron types innervate XIIts, anexcitatory one driving expiratory-linked XIIts firing and an inhibitoryone not strongly recruited during normal respiration .Another idea is that RAm neurons are exclusively excitatory andsynapse on both XIIts MNs and inhibitory neurons in or near XIIts,although two observations make this less likely. First, EPSPsand IPSPs evoked in XIIts by electrically stimulating RAm hadsimilarly short latencies, inconsistent with an interposed inhibitoryneuron; second, we detected only one XIIts cell type (i.e., MNs),suggesting that RAm axons in XIIts terminate on MNs and not oninterneurons.

    fig.ommittedj'56, http://www.100md.com

     Partial schematic of ipsilateral pathways involved during normal (quiet) respiration (left) and song playback/singing (right). During normal respiration, XIIts activity is controlled primarily by expiratory-linked RAm neurons, whereas telencephalic influence from RA is negligible (dashed lines). The respiratory rhythm, generated in or channeled through the rostral nucleus of the ventrolateral medulla (RVL), is relayed via excitatory synapses to RAm (ex) neurons that make glutamatergic synapses on XIIts MNs and to RAm bulbospinal (BS) neurons that project to the expiratory motor neurons (exp MNs). During song playback/singing, RA appropriates control of brainstem circuits for both respiration and syringeal function. Neurons in ventral RA make excitatory (glutamatergic) synapses on XIIts MNs, whereas dorsal RA neurons make as yet functionally uncharacterized synapses on RVL and on a population of RAm (in) neurons that form inhibitory [glycinergic (gly)] synapses on XIIts MNs. These inhibitory inputs from RAm to XIIts delay XIIts MN activity sufficiently to allow formation of the pressure head generated by the expiratory MNs, thus facilitating syringeal (vocal) and respiratory integration. Numbers (1-3) suggest the sequential timing of the different components of the respiratory-vocal control circuit; phase delays between the respiratory versus vocal muscle groups also could be established within RA (i.e., dorsal vs ventral RA neurons) as well as via other synaptic delays within the brainstem circuitry.

    Regardless, the activation of NMDA receptors on XIIts MNs by the excitatory synaptic input, coupled with the intrinsic propertiesof these cells, may enable XIIts MNs to translate more phasicallyactive inputs, such as those detected at expiratory onset or thatmay arise from RA during singing (Yu and Margoliash, 1996), intoprolonged action potential trains. The intrinsic properties ofXIIts MNs seem well suited for both breathing and singing. Bothin vitro and in vivo, XIIts MNs maintain action potential dischargerates of ~20 Hz. During breathing, this may allow them to brakethe rate of airflow during normally active expiration or otherwiseto maintain bronchial patency, specifically via their innervationof syringeal muscles controlling the syringeal labia (Goller andSuthers, 1996b). Indeed, songbirds with bilaterally sectionedsyringeal nerves audibly wheeze during expiration (Nottebohm,1968; Vicario, 1991a), likely because of bronchial occlusion byflaccid syringeal membranes. In contrast to resting dischargerates, XIIts MN firing rates increase linearly and steeply withinjected current, properties displayed extensively during singing,when XIIts activity rises high above restinglevels.

    In vivo intracellular recordings from XIIts MNs in the anesthetized bird, coupled with song playback to selectively activatetelencephalic song nuclei, provide a useful intermediary betweenreduced slice preparations and chronic recordings in singing birds.Here we extend an earlier extracellular study (Williams and Nottebohm,1985) by showing that BOS playback strongly depolarizes XIItsMNs and sharply decreases postsynaptic impedance, indicative ofexcitatory synaptic drive. This excitation is likely driven byRA synapses on XIIts MNs, because inactivation of HVc (the auditoryafferent of RA) (Doupe and Konishi, 1991; Vicario and Yohay, 1993;Mooney, 2000) abolished XIIts responses (Williams and Nottebohm,1985) and because reverse BOS, which does not excite RA neurons(Yu and Margoliash, 1996; Doupe and Konishi, 1991), failed toevoke subthreshold responses in XIIts MNs. The lack of responsesto reverse BOS, a stimulus that can drive subthreshold responsesin some song nuclei (namely HVc) (Mooney, 2000), indicates thatauditory inputs are highly filtered before reaching XIIts andthus do not reflect connections between auditory brainstem structuresand XIIts. However, because RA also contacts the dorsomedial nucleusof the intercollicularis, which in turn innervates XIIts, at leasttwo sources may drive BOS-evoked XIItsactivity.

    Recently, chronic recordings in zebra finches revealed that BOS playback evokes RA activity patterns similar to those producedduring singing (Dave and Margoliash, 2000). An extension of thisview is that BOS playback can evoke respiratory and vocal activityreminiscent of that in the singing bird. We observed (in two birds)that BOS playback not only excited XIIts but also affected patterningof the expiratory muscle EMG, including distinct peaks of EMGactivity preceding the XIIts MN firing. These observations suggestthat BOS playback activates both dorsal and ventral regions ofRA, ultimately exciting XIIts MNs and RAm bulbospinal expiratory-relatedpremotor neurons (Wild, 1993a,b). How reverse BOS affected expiratorymuscle activity is less clear, but it may point to a general arousaleffect or other auditory inputs to RAm expiratory premotor neuronsin addition to those arising fromRA.1iu.9.$, http://www.100md.com

    Further indications of the influence of RA on RAm was the unexpected finding that XIIts MN excitation could be preceded bya phasic membrane hyperpolarization. This behavior could arisethrough feedforward inhibition driven by RA through the lateralmedulla, because RA projection neurons are excitatory (Perkel,1995) and RA innervates RAm, which, as we show here, providesinhibitory input to XIIts (Wild, 1993b). One idea is that RA selectivelyrecruits otherwise inactive inhibitory inputs to XIIts ,perhaps further enhancing the ability of RA to control the precisionof XIIts MN spike timing during singing (Mainen and Sejnowski,1995). A second idea is that feedforward inhibition to XIIts enablesRA to achieve appropriate phase delays between respiratory andvocal activity during singing. That is, RA could directly exciteexpiratory premotor neurons while indirectly inhibiting XIItsMNs, thereby regulating the relative timing of syringeal and abdominalmuscleactivity.

    In addition to coordinating respiratory and vocal activities, inhibition from ipsilateral and contralateral respiratory areasalso may facilitate coordination of the two syringeal halves.One aspect of the song control system, especially in the zebrafinch, is that projections of RA to the brainstem are primarilyipsilateral (Wild, 1993b; Wild et al., 2000). These ipsilateralprojections contrast markedly with the exquisitely precise bilateralinteractions, including lateralized functional asymmetries, thatthe syrinx exhibits during singing (Suthers, 2000). Although brainstem-to-telencephalonfeedback could participate in such bilateral interactions (Striedterand Vu, 1998), the speed and intricacy of this coordination mayrequire more direct mechanisms. One of these probably involvesthe inhibitory and partly concealed excitatory bilateral projectionsfrom RAm to XIIts that we identified here, consistent with previousanatomical evidence of crossed RAm projections (Wild et al., 2000).Another possible source of a crossed influence on XIIts, however,is the contralateral XIIts, given that electrical stimulationof the hypoglossal root could evoke PSPs in both contralateraland ipsilateral XIIts MNs. The anatomical substrate for this isunclear, because intracellular fills of XIIts MNs do not revealaxon collaterals, and unilateral tracer injections into XIItsdo not retrogradely label contralateral XIIts MNs. However, tracerinjections in XIIts retrogradely label neurons lateral to XIIts(i.e., in medial RAm) but with processes extending into it andaxons terminating in the contralateral XIIts (Wild et al., 2000).Stimulating the XIIts root could evoke PSPs in contralateral XIIts,if some XIIts MN axon collaterals contact these RAm neurons immediatelylateral to XIIts. Ultimately, either half of the telencephaloncould act through crossed projections arising from RAm (and possiblyXIIts) to bilaterally coordinate respiratory and vocalactivity.

    Although the syrinx is uniquely avian, the mechanics of its sound generation resemble those of the vocal folds, and XIItsMNs, like mammalian laryngeal MNs, form the output of a respiratory-vocalcontrol network resembling that in mammals, including possibleinhibitory RAm inputs (Holstege, 1989; Goller and Larsen, 1997;Shiba et al., 1997; Yajima and Hayashi, 1997). In turn, RAm inboth songbirds and mammals receives projections from higher centersvia the midbrain, but the direct projections from RA to RAm andXIIts endow the songbird with a degree of telencephalic controlof learned vocal communication perhaps rivaled only by humans(Wild, 1997; VanderHorst et al., 2000; Jürgens, 2002).0, 百拇医药

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