Projection to the Inferior Colliculus from the Basal Nucleus of the Amygdala

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The Journal of Neuroscience, December 1, 2002, 22(23):10449-10460

Projection to the Inferior Colliculus from the Basal Nucleus of the Amygdala
Robert A. Marsh¹, Zoltan M. Fuzessery², Carol D. Grose¹, and Jeffrey J. Wenstrup¹
¹ Department of Neurobiology and Pharmacology, Northeastern Ohio Universities College of Medicine, Rootstown, Ohio 44272, and ² Department of Zoology and Physiology, University of Wyoming, Laramie, Wyoming 82071

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This report describes a projection from the amygdala, a forebrain center mediating emotional expression, to the inferior colliculus(IC), the midbrain integration center of the ascending auditorysystem. In the IC of mustached bats (Pteronotus parnellii) andpallid bats (Antrozous pallidus), we placed deposits of retrogradetracers at physiologically defined sites and then searched forretrogradely labeled somata in the forebrain. Labeling was mostsensitive in experiments using cholera toxin B-subunit astracer.
We consistently observed retrograde labeling in a single amygdalar subdivision, the magnocellular subdivision of the basalnucleus (Bmg). The Bmg is distinctive across mammals, containingthe largest cells in the amygdala and the most intense acetylcholinesterasestaining. Labeled amygdalar cells occurred ipsilateral and contralateralto IC deposits, but ipsilateral labeling was greater, averaging72%. Amygdalar labeling was observed after tracer deposits throughoutthe IC, including its central nucleus (ICC). In comparison, labelingin the auditory cortex (layer V) was heavily ipsilateral (averaging92%). Cortical labeling depended on the location of IC deposits:dorsomedial deposits resulted in the most labeled cells, whereasventrolateral deposits labeled few or no cortical cells. Corticallabeling occurred after several deposits in the ICC. Across experiments,the average number of labeled cells in the amygdala was similarto that in the auditory cortex, indicating that the amygdalocollicularprojection issignificant.
The results demonstrate a direct, widespread projection from the basal amygdala to the IC. They also suggest the presenceof a rapid thalamoamygdalocollicular feedback circuit that mayimpose emotional content onto processing of sensory stimuli ata relatively low level of an ascending sensorypathway.

Key words: amygdala; auditory pathways; auditory cortex; bat; chiroptera; cholera toxin; emotion; inferior colliculus

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The amygdala is a collection of diverse, interconnected nuclei (Johnston, 1923; Pitkänen et al., 1997; Swanson and Petrovich,1998) that impart appropriate emotional import to biologicallyrelevant sensory stimuli. Its functions include learning the emotionalsignificance of sensory input, attentional and motivational processing,and mediating autonomic responses to emotion-laden stimuli (Gloor,1972; Kaada, 1972; Cahill and McGaugh, 1998; LeDoux, 2000). Tosupport these functions, the amygdaloid nuclei receive extensivesensory input from unimodal and polymodal sensory cerebral cortices(Price et al., 1987; McDonald, 1998; Stefanacci and Amaral, 2000)and from some subcortical sensory structures (LeDoux et al., 1985;Yasui et al., 1987; Linke et al., 1999). In turn, amygdaloid nucleiproject to sensory association cortices (Krettek and Price, 1977a;Amaral and Price, 1984; Iwai and Yukie, 1987), to forebrain areasassociated with emotions and memory (Krettek and Price, 1977a,b;McDonald, 1996; Swanson and Petrovich, 1998), and to the hypothalamusand lower centers mediating autonomic output (LeDoux et al., 1988;Feldman et al., 1995; Pitkänen et al., 2000). The present studyprovides the first evidence of a direct and widespread projectionfrom the basal amygdala to the inferior colliculus (IC), obtainedin two species of bats. The results suggest the presence of anauditory-amygdalar feedback circuit to the IC that may imposeemotional content onto processing of sensory stimuli at a lowlevel of an ascending sensorypathway.

The IC occupies a crucial position in the primary auditory pathway, integrating input from a broad range of auditory brainstemnuclei and relaying information to the auditory thalamus and tonuclei at the sensorimotor interface. The IC creates selectivityfor various dimensions of behaviorally relevant sounds, includingselectivity for location (Faingold et al., 1991; Park and Pollak,1994), duration (Casseday et al., 1994; Fuzessery, 1994; Fuzesseryand Hall, 1999), direction of frequency-modulated sweeps (Fuzessery,1994; Fuzessery and Hall, 1996), and combinations of acousticelements in vocalizations (Mittmann and Wenstrup, 1995; Portforsand Wenstrup, 1999; Leroy and Wenstrup, 2000; Wenstrup and Leroy,2001). The IC also receives extensive auditory corticofugal input(Saldaña et al., 1996; Winer et al., 1998) and monoaminergic(Klepper and Herbert, 1991) projections capable of modulatingthis response selectivity (Yan and Suga, 1996, 1999; Hurley andPollak, 1999). The IC thus functions as an integration centermediating interactions between higher and lower auditory centersand nonauditory inputs. A projection from the amygdala to theIC indicates a major addition to the factors affecting informationprocessing in the IC, imparting emotional context onto processingin the primary auditorypathway.

The results presented here were observed unexpectedly during the course of tract-tracing studies designed to identify theorigin of inputs to functionally specialized neurons in the IC.These experiments demonstrate a significant projection from thebasal nucleus of the amygdala that is distributed widely throughoutthe IC, including most of the central nucleus (ICC), the majorrecipient of ascending auditory brainsteminput.

Parts of this paper have been published previously in abstract form (Marsh et al., 1999).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We deposited retrograde tracers in the IC in two species of bats and examined the pattern of labeling in the forebrain. Mustachedbats (Pteronotus parnellii) were captured in Jamaica or Trinidadand Tobago, West Indies. Pallid bats (Antrozous pallidus) werecaptured in Arizona. Brainstem or thalamic labeling in some experimentson mustached bats has been reported previously (Wenstrup and Grose,1995; Wenstrup et al., 1999). All procedures were approved bythe Institutional Animal Care and Use Committee of the NortheasternOhio Universities College ofMedicine.

Surgical procedures. Surgical and recording procedures were similar to those reported previously for mustached bats (Wenstrupet al., 1999) and pallid bats (Fuzessery and Hall, 1996). Twoto 3 d before surgery, tetracycline was placed in the drinkingwater to reduce postsurgical infection. To surgically expose theIC, animals were anesthetized with methoxyflurane (Metofane; Schering-PloughAnimal Health, Omaha, NE) in combination with sodium pentobarbital(Nembutal, 5 mg/kg, i.p.; Abbot Laboratories, North Chicago, IL)and acepromazine (2 mg/kg, i.p.; Med-Tech, Buffalo, NY). A midlineincision was made over the dorsal surface of the skull; then,the skin and muscles were reflected laterally. In mustached bats,a tungsten ground electrode was cemented into the skull overlyingthe right cerebral hemisphere. In pallid bats, a ground electrodewas placed in contact with the temporal muscles on the left side.A metal pin was glued to the skull to position the head in thestereotaxic apparatus, and a small hole (<0.5 mm in diameter)was placed in the skull over the IC. Lidocaine (Elkins-Sinns,Cherry Hill, NJ) was applied to the surgical wound. After surgery,mustached bats were placed in a holding cage for at least 24 hr,whereas pallid bats were used in experiments on the day of thesurgery.

Acoustic stimulation and recording. Physiological recordings were obtained from bats placed in a Plexiglas restraining apparatusand housed in a humidified, soundproof chamber lined with anechoicfoam. Computer-controlled acoustic signals (3-50 msec duration,0.5 msec rise-fall times, three to four per second) consistedof tone bursts, noise bursts, frequency-modulated sweeps, or combinationsof these. The signals were generated separately [model 8904A (Hewlett-Packard,Palo Alto, CA) or model 395 (Wavetek)], switched (model SW2; Tucker-DavisTechnologies, Gainesville, FL), and attenuated (model PA4; Tucker-DavisTechnologies). Signals from the separate channels were summed(model SM3; Tucker-Davis Technologies), amplified (model HCA-800II;Parasound, San Francisco, CA), and then sent to a speaker (leaftweeter; Technics). The speaker was placed 10 or 30 cm away fromthe bat and 25° into the sound field contralateral to the IC understudy. Acoustic properties of the entire system were tested witha calibrated microphone (model 4135; Brüel and Kjær, Norcross,GA) placed in the position normally occupied by the bat's head.Distortion components in the speaker were not detectable 60 dBbelow the signal level, as measured by an application performinga fast Fourier transform of the digitized microphone signal (modelNB-A2000; National Instruments, Austin,TX).

Mustached bats were lightly anesthetized with Metofane and placed in a Plexiglas restraining apparatus; all animals recoveredbefore recording started. If signs of distress or discomfort wereevident, mustached bats received subdermal injections of acepromazine(2 mg/kg), or they were removed from the experimental apparatus.Pallid bats were kept lightly anesthetized during the experimentsby sodium pentobarbital booster injections (2.5 mg/kg, i.p.) asnecessary.

The evoked activity of single and/or multiunit responses was recorded from the IC of the bats. Recordings were obtained withmicropipette electrodes filled with saline (0.9% NaCl) or PBS,pH 7.4, and one of the following tracers: 1-2% cholera toxin B-subunit(CTb) (List Biologic, Campbell, CA), 2% Fluoro-Gold (FG) (Fluorochrome,Englewood, CO), 2% dextran-conjugated rhodamine [Fluororuby (FR);Molecular Probes, Eugene, OR], or 2% wheat germ agglutinin conjugatedto horseradish peroxidase (WGA-HRP) (Sigma, St. Louis, MO). Electrodeswere broken to tip diameters of 5-10 µm, with resistances of 3-20M $Omega$ . Electrodes were placed visually over the IC and advanced bya hydraulic micropositioner (model 650; David Kopf Instruments,Tujunga, CA). Extracellular action potentials were amplified,filtered (bandpass, 500-6000 Hz), and sent to a window discriminator(model 74-60-3; Fredrick Haer Company, Bowdoinham, ME). The pulseoutput of the window discriminator was digitized at 10 kHz (modelNB-MIO-16X; National Instruments) for analysis of peristimulustime histograms, raster displays, and statistics on the neuralresponses. The neural responses analyzed consisted of isolatedsingle-unit responses with a high signal-to-noise ratio or multiunitactivity of stimulus-locked clusters of clearly definedspikes.

By use of tonal stimulation, recording sites were characterized by their best frequency (the frequency that elicited a responseat the lowest sound level) and threshold at best frequency (lowestsound level at best frequency that elicited stimulus-locked spikes).Best frequencies were measured with a resolution of 0.01 or 0.1kHz but are expressed in kilohertz. Depending on the experiment,we also assessed rate-level functions, latency of response, andsensitivity to frequency-modulated sweeps, noise, and combinationsof tones. When recording multiunit responses, sites were sampledat 100-200 µm intervals through dorsoventral penetrations of theICC. Single units were tested as they were isolated. At the endof a penetration, the tracer-filled recording electrode was returnedto the location receiving the iontophoretic deposit. Responseswere again characterized and then a deposit was made using pulsedcurrent (+1-5 µA; 3.5-10 min duration; 50% duty cycle). Afterthe deposit, the electrode was maintained in position for 5 minand then removed from thebrain.

Histology and tracer techniques. After tracer deposits, the bats were returned to their holding cages for an appropriate survivaltime (see below). For perfusion, the animals were deeply anesthetizedwith Nembutal (>60 mg/kg, i.p.). When nociceptive reflexes wereeliminated, the chest cavity was opened, and the animal was perfusedthrough the heart with PBS and an aldehyde fixative. After thebrain case was opened, the brain was blocked in a consistent plane(the plane of most electrode penetrations). For the mustachedbats, this was inclined ~15% from dorsocaudal to ventrorostral(Wenstrup et al., 1994, 1999). For pallid bats, brains were blockedin the frontal plane, perpendicular to the dorsal surface. Eachbrain was refrigerated overnight in a 30% sucrose-PBS solution,pH 7.4, before sectioning. The brain was sectioned transverselyon a freezing microtome at a thickness of 30 or 40 µm. All sectionsfrom the cochlear nucleus to the frontal cortex were collectedin cold 0.1 M phosphate buffer or PBS. Three alternating serieswere collected and processed by different protocols; one serieswas stained with cresylviolet.

The results are based primarily on experiments using CTb as tracer. In these, animals were perfused with a 4% paraformaldehydefixative 3-5 d after the tracer was deposited. Tracer was visualizedusing immunohistochemistry and an avidin-biotin-peroxidase procedure(Vector Laboratories, Burlingame, CA). After blocking in 3% normalrabbit serum plus 0.2% Triton X-100, free-floating sections wereincubated in goat anti-CTb (1:20,000 or 1:40,000; List Biologic)for 60-65 hr at 4°C. Heavy metal-intensified diaminobenzidinewas used as achromogen.

We also examined labeling patterns from experiments in which FG, FR, and WGA-HRP were used (Wenstrup et al., 1999). Animalswere perfused 5-10 d after FG or FR deposits with a 4% paraformaldehydefixative; subsequently, sections were mounted, cleared, and coverslippedwith DPX. Animals were perfused 24-48 hr after WGA-HRP depositswith a mixed aldehyde fixative and a sucrose phosphate buffersolution. Tetramethylbenzidine was used aschromogen.

Acetylcholinesterase (AChE) staining in the forebrain was examined using methods outlined by Hardy et al. (1976). Animalswere perfused with 4% paraformaldehyde fixative, and then thebrains were removed and placed in 30% sucrose overnight. Aftersectioning, brains were rinsed in 0.1 M acetate buffer, and free-floatingsections were processed using the thiocholine method for AChEvisualization.

Data analysis. Cell bodies were considered to be labeled by CTb only when immunohistochemical reaction product at least partiallyfilled a somatic profile. Labeled cells were thus distinct fromperoxidase labeling of red blood cells, some endothelial cells,or extracellular debris. Similar criteria were used for othertracers. Retrogradely labeled cells in the amygdala, auditorycortex, and brainstem were plotted using a drawing tube underbright-field illumination for CTb, fluorescence for FG or FR,and dark-field illumination for WGA-HRP [268-468×; numerical aperture(NA), 0.7; plan apochromat]. Plots of subdivisions and labeledcells were drawn separately and scanned at 300 dots per inch andthen imported into a graphics application [Canvas (Deneba Systems,Miami, FL) or Corel Draw (Corel, Ottawa, Ontario, Canada)]. Countsof labeled cells were made from every section in one series. Instatistical tests, the null hypothesis was rejected when its probabilitywas <5%.

Potential sources of artifact were examined. We studied whether immunohistochemical processing for CTb artifactually labeledcells in the amygdala. The labeling pattern in the amygdala wascompared with material from previous experiments in our laboratoryin which CTb was deposited in the medial geniculate body (MGB)(Wenstrup and Grose, 1995). Using processing methods identicalto those used here, that material had no labeled somata in theamygdala. We also found no evidence of transsynaptic transportof CTb in either anterograde or retrograde directions after ICdeposits. For instance, we observed no somatic labeling in themedial nucleus of the trapezoid body, which projects indirectlyto the IC. Transsynaptic anterograde labeling of amygdalar neuronsafter IC deposits requires both somatic labeling in or near theMGB and terminal labeling in the amygdala. We observed neitherofthese.

Photomicrographs were taken under bright-field illumination using an Olympus Provis microscope (model AX70; Olympus Optical,Tokyo, Japan) with a Spot digital camera (model 1.4.0; DiagnosticInstruments, Sterling Heights, MI) and associated software. Gray-scaleimages were imported into Photoshop (Adobe Systems, San Jose,CA), in which global adjustments in brightness and contrast weremade. Individual images were imported into Canvas (Deneba Systems),in which composite plates wereconstructed.

Subdivisions of the amygdala were identified from Nissl-stained and cholinesterase-stained sections, based on previous workin rats, cats, and monkeys (Ben-Ari et al., 1977; Krettek andPrice, 1978b; Price et al., 1987; Alheid et al., 1995). Nomenclaturefor amygdalar nuclei follows that described by Price et al. (1987).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

These results are based on deposits of retrograde tracers within tonotopically organized regions of the IC in 11 mustachedbats and 12 pallid bats. Tracer deposits in most parts of theIC resulted in labeling of the basal nucleus of the amygdala.We first outline the architectonic subdivisions of the amygdalain these animals and then describe features of IC tracer depositsand retrograde labeling in theamygdala.

Anatomic organization of the amygdala

In mustached and pallid bats, the general location and cellular architecture of the amygdala conforms to that described previouslyin other bats (Johnston, 1923; Humphrey, 1936) and in rats andcats (Krettek and Price, 1978b; Price et al., 1987; Alheid etal., 1995). Briefly, the amygdala lies in the forebrain, boundeddorsally by the hippocampus, caudate-putamen, or lateral ventricle(Fig. 1). Laterally, it is bounded by the external capsule andpiriform cortex. Medially, it is limited by the edge of the cerebralhemisphere or by the internal capsule. Subdivisions describedhere are based primarily on Nissl- and cholinesterase-stained(AChE) sections. Figure 1, A and C, shows major nuclei in mustachedand pallid bats using Nissl-stained transverse sections. Nucleargroups were delineated by cell size, intensity of Nissl stain,nuclear location and shape, and association with fiber tracts.

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Figure 1. Views of the amygdala and other forebrain structures in mustached and pallid bats. A, Nissl-stained coronal section in the mustached bat shows large lateral nucleus (L) and darkly stained magnocellular division of the basal nucleus (Bmg). B, Cholinesterase-stained section in mustached bat shows staining of Bmg and caudate-putamen. Section is from a different animal than the section in A. C, Nissl-stained coronal section in the pallid bat. D, Cholinesterase-stained section in the pallid bat shows staining of Bmg and caudate-putamen. Sections in C and D are from the same animal. Protocol for photomicrographs is as follows (plan apochromat): A, C, NA 0.08; B, D, NA 0.16. The following anatomic abbreviations are used throughout figure legends: AB, accessory basal nucleus of the amygdala; ALD, anterolateral division of the central nucleus of the inferior colliculus; Bmg, magnocellular subdivision of the basal nucleus of the amygdala; Bpc, parvicellular subdivision of the basal nucleus of the amygdala; CE, central nucleus of the amygdala; COp, posterior cortical nucleus of the amygdala; CPu, caudate-putamen; DC, dorsal cortex of the inferior colliculus; DPD, dorsoposterior division of the central nucleus of the inferior colliculus; ec, external capsule; En, endopiriform nucleus; Ex, external nucleus of the inferior colliculus; Hip, hippocampal formation; Hyp, hypothalamus; I, intercalated nuclei of the amygdala; IC, inferior colliculus; ICC, central nucleus of the inferior colliculus; int, internal capsule; L, lateral nucleus of the amygdala; ll, lateral lemniscus; LV, lateral ventricle; M, medial nucleus of the amygdala; MD, medial division of the central nucleus of the inferior colliculus; MGB, medial geniculate body; opt, optic tract; PAC, periamygdaloid cortex; PAG, periaqueductal gray; Pir, piriform cortex; rf, rhinal fissure; Tem, temporal cortex; wm, white matter underlying cerebral cortex.

Deposits of tracer placed in the IC resulted in retrograde labeling of cells in the basal nucleus of the amygdala. We recognizetwo subdivisions, magnocellular (Bmg) and parvicellular (Bpc).Cell bodies in the Bmg were the largest in the amygdaloid complexand had characteristically intense Nissl staining (Fig. 1A,C).Cells in the Bpc were smaller but still larger than most neuronsin the amygdala. The basal nucleus, and in particular the Bmg,can be additionally differentiated from other amygdaloid nucleiby intense staining for AChE (Ben-Ari et al., 1977; Price et al.,1987), the result of cholinergic input from nucleus basalis inthe substantia innominata (Nagai et al., 1982; Woolf and Butcher,1982). Despite differences in background staining, the most intenseAChE staining in both mustached and pallid bats occurred in theBmg (Fig. 1B,D). The Nissl and AChE stainings of the amygdalaprovide the primary bases for identifying the Bmg as the siteof retrograde labeling after tracer deposits in theIC.

The large neurons of the Bmg occurred in the medial part of the basal nucleus, similar to rats (Price et al., 1987). However,it was limited approximately to the central one-half of the basalnucleus, more similar to the caudorostral position reported inmonkeys (Price et al., 1987). Cells in the rostral part of thebasal nucleus are similar in size, density, and intensity of Nisslstaining to those in the caudolateral part of the nucleus, whichwe called Bpc. The Bmg corresponds to the anterior subdivisionof the basolateral nucleus in other parcellation schemes (Krettekand Price, 1978b; Alheid et al., 1995).

Retrograde tracer deposits in the IC

In most experiments, a single deposit of the tracer CTb was placed in a physiologically defined region of the IC (Fig. 2,Table 1). The physiological recording established the locationof the deposit sites within the tonotopic organization of theIC (Fig. 2A,C).

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Figure 2. Location of tracer deposits and tonotopic organization in the IC of mustached bats (A, B) and pallid bats (C, D). A, Schematic view of the tonotopic organization in mustached bat's IC, with location of CTb tracer deposits indicated. Frequencies in lower part of audible range (10-59 kHz) are represented systematically in the anterolateral division (ALD) of ICC. The dorsoposterior division (DPD) disproportionately represents frequencies in the 59-63 kHz range, whereas frequencies >63 kHz are represented in the medial division (MD). B, Deposit of CTb in a mustached bat's ICC at site tuned to 86.1 kHz (case 5). C, Schematic view of the tonotopic organization of the pallid bat's IC, with the location of CTb tracer deposits indicated. D, Deposit of CTb in a pallid bat's ICC at site tuned to 41.9 kHz (case 20). In A and C, gray lines and text indicate isofrequency lines in the IC. Protocol for all photomicrographs is as follows (plan apochromat): NA 0.16.


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Table 1. Summary of physiological responses and retrograde labeling after tracer deposits in the IC

In the mustached bats, deposits were made across a broad frequency range, from 23 to 89 kHz, encompassing much of this bat'saudible range of ~10-120 kHz. In this species, the tonotopic organizationof the ICC is present in modified form because of the disproportionaterepresentation of frequencies near 60 kHz (Zook et al., 1985;O'Neill et al., 1989). All tracer deposits were associated withfrequencies used in both the bat's multiharmonic sonar signaland its repertoire of social communication signals (Novick, 1963;Kanwal et al., 1994). CTb deposits in five experiments were placedat sites tuned to 80-89 kHz. All of these sites showed combinatorialresponse properties, in which the response to the 80-89 kHz signalwas modulated by a signal in the 25-30 kHz frequency range (Mittmannand Wenstrup, 1995; Portfors and Wenstrup, 1999). Figure 2B showsone of these deposits, placed at a combination-sensitive recordingsite that was tuned to 86 kHz and facilitated by a 27 kHz signal.Other CTb deposits were placed at 23 and 59 kHz, frequencies usedin the first and second harmonics of the sonar call. In additionto these CTb experiments, we also describe results from threeexperiments using FG as the tracer and one experiment each usingFR and WGA-HRP.

Deposits of CTb were made in 11 pallid bats. Compared with the mustached bat, the tonotopic organization of the IC in thisspecies is generally more conventional, with frequency increasingfrom dorsal to ventral and isofrequency contours extending fromdorsomedial to ventrolateral (Fuzessery, 1994). CTb deposits weredistributed throughout the mediolateral extent of two frequencyband representations (Fig. 2C, Table 1). In five animals, CTbdeposits were placed in the 39-42 kHz representation, a regiondominated by selective responses to downward frequency-modulatedsweeps used in the animal's sonar signal (Fuzessery, 1994). Figure2D shows a CTb deposit site responsive to 42 kHz, located approximatelymidway between the medial and lateral edges of the IC. In thesix other CTb experiments, deposits were placed at recording sitesin the 15-25 kHz range. These frequencies are used in prey detectionand social communication but not in sonar (Brown, 1976; Bell,1982; Fuzessery et al., 1993). The most lateral part of this frequencyrepresentation (Fig. 2C, deposits 16 and 17) is physiologicallydistinct (Fuzessery, 1997) and has unusual anatomic features (Wenstrupet al., 1996). We also report data from one experiment in which12 deposits of WGA-HRP were made in the lateral two-thirds ofthe IC at recording sites with best frequencies ranging from 13to 65kHz.

Retrograde labeling in the amygdala

After deposits of CTb in the IC, retrograde labeling was observed in the amygdala. Amygdalar labeling resulting from the depositsin Figure 2, B and D, is illustrated in photomicrographs (Fig.3) and as plots of labeled cells in a series of coronal sections(Fig. 4). These figures document the major qualitative featuresof the labeling: it was bilateral, it was found exclusively inthe Bmg, and it was similar for both mustached and pallid bats.

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Figure 3. Retrograde labeling in Bmg after tracer deposits in the IC. A, C, Lower-power (A) and higher-power (C) views of retrograde labeling in the ipsilateral Bmg of the mustached bat after the CTb deposit illustrated in Figure 2B. B, D, Lower-power (B) and higher-power (D) views of retrograde labeling in the ipsilateral Bmg of the pallid bat after the CTb deposit illustrated in Figure 2D. Retrograde neuronal labeling is restricted to the Bmg. Examples of artifactual label are evident in C (far left) and D (top). Protocol was as follows (plan apochromat): A, B, NA 0.08; C, D, NA 0.40.

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Figure 4. Distribution of retrograde label in the amygdala after tracer deposits in the IC. A, Labeling in a mustached bat after tracer deposit shown in Figure 2B. B, Labeling in a pallid bat after tracer deposit shown in Figure 2D. Sections are arranged from caudal (top) to rostral (bottom), and the labeling on the side ipsilateral to the deposit is presented on the left. In both experiments, labeling was bilateral with an ipsilateral predominance. Outline of the Bmg is in bold.

Quantitative analyses described below are based only on CTb experiments, because there were many fewer labeled cells in theamygdala after FG, FR, or WGA-HRP deposits (see below). Labelingof the Bmg was bilateral but with an ipsilateral dominance (Fig.4, Table 1). Across all CTb experiments in which at least 40amygdalar cells were labeled, 72% of the amygdalar label was ipsilateral.However, there was a clear species difference. In mustached bats,ipsilateral labeling accounted for 84% (range, 71-93%) of labeledcells in the amygdala. In pallid bats, ipsilateral labeling wasless dominant, averaging 61% of amygdalar labeling (range, 54-70%).This difference is highly significant (p < 0.0002; ttest).

Labeling in the basal nucleus was restricted to its caudal two-thirds, in which the magnocellular subdivision is located.Figure 5 shows the caudorostral distribution of label across theentire basal nucleus for each experiment in which at least 40amygdalar cells were labeled. The label extends from ~20-65% ofthe caudal-to-rostral dimension of the basal nucleus, correspondingclosely to the location of Bmg. This was true for the mustachedand pallid bats on both the ipsilateral and contralateral sides.

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Figure 5. Caudal-to-rostral pattern of retrograde labeling in Bmg. Retrograde labeling is expressed as the percentage of total labeling in increments of the caudal-to-rostral extent of the entire basal nucleus. A, Labeling in the mustached bat on the ipsilateral (IPSI) and contralateral (CONTRA) sides. B, Labeling in the pallid bat. Black arrowheads indicate the caudal and rostral borders of the Bmg as discussed in Results (lower tip indicates average border across animals; top, lateral tips indicate range of borders).

Most CTb deposits resulted in significant labeling of the amygdala ( $>=$ 8% of all labeling), including deposits clearly centeredwithin the ICC (Fig. 2; Table 1, animals 1, 3-7, 14, 15, 20),as well as others in the dorsal or dorsomedial IC that may haveextended into the dorsal cortex (Table 1, animals 2, 13, 18,19). The ICC was identified both by architecture (Zook et al.,1985) and by brainstem inputs from the medial and lateral superiorolivary nuclei (Wenstrup et al., 1996, 1999). Amygdalar labelingwas observed after deposits placed in different frequency representationsand across the mediolateral extent of the IC. Weak labeling wasobserved only in the dorsomedial extreme of the IC (3%, animal12), in which the low number of total labeled cells in that experimentsuggests poor sensitivity, and in the ventrolateral extreme (1-2%,animals 21 and 22), in which the result appears more reliable.However, within the area of IC in which deposits significantlylabeled the amygdala, there was variability in the numbers ofretrogradely labeled cells and in the percentage of total labeling.We found no clear trend to explain thisvariability.

Comparison with cortical and brainstem labeling

To provide a reference for the efficacy of retrograde transport to the amygdala, it was compared with brainstem and auditorycortical inputs to the IC. Retrograde labeling was observed inlayer V of auditory cortex in all CTb cases (Table 1, Fig. 6).Nearly all labeled cells were located ipsilaterally. Across allCTb experiments in which at least 40 cortical cells were labeled(seven mustached bats and five pallid bats), the auditory corticallabel was on average 92% ipsilateral (range, 85-96%). There wasno species difference in the predominance of ipsilateral labeling.Cortical labeling varied with location of the IC deposit site(Fig. 2, Table 1). Dorsomedial deposits resulted in the mostlabeled cells, whereas ventrolateral deposits generally resultedin few or no labeled cortical cells. However, cortical labelingoccurred after deposits restricted to the ICC (animals 1, 3-7,14, 20).

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Figure 6. Retrograde labeling in ipsilateral auditory cortex after CTb tracer deposits in the IC. Roman numerals indicate cortical layers. A, Labeling in a mustached bat (Fig. 2A,B, case 5). Retrograde transport to the amygdala after the ICC deposit is shown in Figures 3A and 4A. B, Labeling in a mustached bat (Fig. 2A, case 2). C, Labeling in a pallid bat (Fig. 2C,D, case 20). Retrograde transport to the amygdala after the ICC deposit is shown in Figures 3B and 4B. D, Labeling in a pallid bat (Fig. 2C, case 13) after four CTb deposits in regions tuned near 15 kHz. Protocol for all photomicrographs was as follows (plan apochromat): NA 0.16.

Labeling in the amygdala often constituted a significant fraction of the total number of retrogradely labeled cells afterIC deposits. Figure 7 and Table 1 compare the percentage of totalretrograde labeling found in the auditory brainstem, amygdala,and auditory cortex (excluding labeling in the IC). Amygdalarlabeling ranged from 1 to 32% of total labeling, averaging ~15%.In comparison, auditory cortical labeling averaged 20%, whereaslabeling in the auditory brainstem averaged 64%. The number oflabeled cells in the amygdala was not significantly differentfrom the number in the auditory cortex for either mustached batsor pallid bats (paired t tests; p > 0.4), but both were significantlyless than labeled cells in the auditory brainstem (paired t tests;p < 0.001 for each test). The mean value of percentages for eachanatomic region was nearly identical between the mustached batand pallid bat experiments (Fig. 7).

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Figure 7. Comparison of retrograde labeling in brainstem, auditory cortex, and amygdala after CTb deposits in the IC of mustached bats and pallid bats. The relative distribution of label in the two species is nearly identical, despite wide variation among individual cases. Columns indicate average percentage of labeling in the three brain regions; vertical lines indicate the range of values.

Comparison of retrograde tracers

We analyzed experiments using FG, FR, and WGA-HRP to compare the sensitivity of retrograde labeling with CTb (Table 1). Intwo of the FG cases, the FR case, and one WGA-HRP case, retrogradelabeling in the amygdala was confirmed. However, the FG depositslabeled few or no cells in the amygdala, even when retrogradelabeling in the auditory brainstem was robust. In addition, labelingin the auditory cortex was also weak. In one experiment usingWGA-HRP, three tracer deposits were made at sites tuned to 28-31kHz. Despite the large deposit zone, strong anterograde labelingin the MGB (Wenstrup and Grose, 1995, their Fig. 3), and robustretrograde labeling in the brainstem (Table 1), only 19 cells(0.3%) were labeled in the amygdala. No other experiment involvingWGA-HRP deposits in any frequency representation of the IC (of12 mustached bats and eight pallid bats examined) revealed labelingof the amygdala. Particularly noteworthy was one experiment inthe pallid bat in which 12 tracer deposits were placed in thelateral two-thirds of the IC (Table 1). Although retrograde labelingof the auditory brainstem was robust, no cells were labeled ineither the amygdala or auditorycortex.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Retrograde tracers placed in the IC of two bat species labeled cells in the Bmg of the amygdala. This surprising result indicatesa significant, direct projection from Bmg to IC, one that couldmodify the processing of sound early in the ascending auditorypathway on the basis of an animal's emotional or motivationalstate.

Reliability of the finding

Because an amygdalocollicular projection has not been described previously, alternative interpretations of retrograde amygdalarlabeling were considered. Artifactual immunohistochemical labelingwas ruled out by comparison with experiments depositing CTb intothe MGB (Wenstrup and Grose, 1995). We also found no evidenceof transsynaptic transport of CTb in either the anterograde orretrograde direction, consistent with previous studies in otherspecies (Robertson and Grant, 1985; Luppi et al., 1990). Finally,although CTb labeling can result from uptake by fibers of passage(Chen and Aston-Jones, 1995), it is highly unlikely to explainthe present results. Here, uptake by amygdalar fibers of passagecould not occur unless bundles of axons originating from the ipsilateraland contralateral Bmg invaded nearly every part of the IC, withouttermination, en route to other targets. No known Bmg projectioncan account for this unlikely scenario (Price et al., 1987; Swansonand Petrovich, 1998; Pitkänen et al., 2000). In addition, thecentral amygdaloid nucleus, with demonstrated amygdalar projectionsto midbrain and brainstem autonomic centers near IC (Krettek andPrice, 1978a; Rizvi et al., 1991), wasunlabeled.

Two observations strengthen our interpretation of the result. First, we found retrograde labeling in Bmg after IC injectionsof other tracers, although fewer amygdalar cells were labeled.The greater sensitivity of retrograde labeling in CTb experimentsagrees closely with previous studies (Luppi et al., 1990, 1995;Peyron et al., 1998; Wenstrup et al., 1999). Second, the superiorsensitivity of retrograde labeling by CTb was similarly evidentin the auditory corticocollicular projection to the ICC. We thereforeconclude that retrograde labeling in the Bmg after CTb depositsin the IC demonstrates a direct projection of Bmg neurons ontoneurons of the IC, including theICC.

Forebrain projections to the IC

In both species, these experiments revealed two forebrain projections to the IC: from Bmg and auditory cortex (Fig. 8). Becausecorticocollicular projections have been described previously [inthe mustached bat (Fitzpatrick et al., 1998)] [in other species(Huffman and Henson, 1990; Herbert et al., 1991; Winer et al.,1998)], we compare the expected corticocollicular projection withthe unexpected amygdalocollicular projection.

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Figure 8. Summary of the neural connections demonstrated in this article. Both the auditory cortex and basal nucleus of the amygdala project to the IC bilaterally. The strongest projection, in terms of the number of projection neurons, is the ipsilateral auditory cortex, followed in descending order by the ipsilateral Bmg, contralateral Bmg, and contralateral auditory cortex.

Auditory cortical projections from layer V pyramidal cells were strongest to dorsomedial regions of the IC and weakest toventrolateral regions nearest the lateral lemniscus. The corticocollicularprojection includes the ICC, thus supporting results by Saldañaet al. (1996) showing a significant cortico-ICC projection inrats. These results support the existence of a direct, excitatory(glutamatergic) projection to the ICC that may have excitatoryor, via interneurons, inhibitory effects. Indeed, auditory corticalstimulation can evoke either inhibitory or excitatory interactionsamong IC neurons (Mitani et al., 1983; Syka and Popelar, 1984;Sun et al., 1989), and the sign of the interaction is criticallydependent on the match between cortical and collicular responseproperties (Yan and Suga, 1996, 1999; Ma and Suga, 2001; Yan andEhret, 2001). The specificity of these physiological effects mayreflect the topographic specificity of the corticocollicular projection(Saldaña et al., 1996).

The amygdalocollicular projection is mediated by cells in one subdivision, the Bmg. Because of the size and large numbersof labeled cells, it is probable that principal cells are themain contributor to this projection. Like the cortical projectionneurons, Bmg principal neurons are pyramidal cells (McDonald,1982; Millhouse and de Olmos, 1983), immunopositive for excitatoryamino acids (McDonald, 1996), and likely to provide direct, excitatoryeffects, as well as inhibitory effects, mediated through collicularinterneurons.

Bmg neurons throughout its caudorostral extent project to the IC. Furthermore, these neurons may terminate throughout muchof the IC, because Bmg seems to be similarly labeled by IC depositsin lower- and higher-frequency representations and in medial andlateral locations. This contrasts with the corticocollicular projection,which terminates in more restricted regions of IC (Saldaña etal., 1996). Thus, the amygdalocollicular pathway may be composedof a more limited population of neurons than the cortical projection,with each amygdalar neuron projecting to more widespread partsof the IC. Anterograde tracing experiments are needed to confirmthis view. Its functional consequence is that the effects of amygdalaractivation on the IC may be more global than corticocolliculareffects.

Functional implications

Amygdaloid nuclei play major roles in establishing the emotional significance of sensory stimuli, in memory storage of emotion-ladensensory events, and in orchestrating emotional responses to sensoryinput (Gloor, 1972; Kaada, 1972; Cahill and McGaugh, 1998; LeDoux,2000). The association of amygdaloid nuclei with auditory processingtakes many forms. For instance, the lateral amygdala receivesdirect projections from both the MGB and auditory cortex (Aggletonet al., 1980; LeDoux et al., 1985; Price et al., 1987). Inputsfrom the MGB, when matched to aversive stimuli, generate long-termchanges in the responsiveness of lateral nucleus neurons to auditorystimuli (Clugnet and LeDoux, 1990; Rogan and LeDoux, 1995). Theseresponse changes in turn produce conditioned autonomic responses,such as increased heart rate and dilated pupils, in response tosounds matched to aversive stimuli (LeDoux et al., 1984; Campeauand Davis, 1995; Amorapanth et al., 2000).

The output of the amygdala also affects information processing and plasticity in auditory cortex (Armony et al., 1998; Cahilland McGaugh, 1998; Weinberger, 1998), mediated by either directamygdaloauditory cortical projections, including from Bmg (Amaraland Price, 1984; McDonald and Jackson, 1987; Yukie, 2002), orindirect projections through the cholinergic basal forebrain orhippocampal formation (Price et al., 1987; Pitkänen et al., 2000).This modulation extends to targets of auditory cortical projections.For example, chemical inactivation of the basal amygdala reducescertain types of conditioned auditory responses in the MGB (Marenet al., 2001; Poremba and Gabriel, 2001). These influences maybe mediated by the amygdalocortical projection from the basalnucleus and in turn through descending corticothalamic projections(Poremba and Gabriel, 2001). However, our results provide an alternativepathway to underlie these observations. Specifically, modificationof auditory responses in thalamus or cortex may result from projectionsof Bmg onto collicular cells, which in turn project onto thalamiccells. Interestingly, amygdalar modification of cortical responseswould also influence the IC via the corticocollicular pathway.Amygdalar modulation may therefore interact with several levelsof the auditory system (Fig. 9).

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Figure 9. Paths by which auditory information is processed in the amygdala and projected back to the IC. Solid lines indicate feedforward projection of auditory information. Dotted lines indicate feedback connections that can include results of amygdalar processing. Sources are as follows: projections from auditory cortex and amygdala to IC (present study); projections from MGB to amygdala in rats (LeDoux et al., 1985); projections from auditory cortex to amygdala in the mustached bat (Fitzpatrick et al., 1998) and in monkeys (Aggleton et al., 1980; Stefanacci and Amaral, 2000); projections from the amygdala, including Bmg, to auditory cortex in other species (Amaral and Price, 1984; McDonald and Jackson, 1987); many additional connections exist between amygdaloid nuclei and auditory cortex.

The role of the amygdalocollicular projection is speculative at this point; several possibilities are suggested. The firstwould be generally applicable if this pathway were present inother species: that emotional memories, applied to the processingof incoming signals at the IC, could shift the focus of processingon the basis of previous experience with these signals. The presentresults suggest that directed attention to attractive or aversivesignals could be initiated at the midbrainlevel.

Other possibilities, although perhaps best documented in bats, may apply to other species with specialized IC processing.For example, the amygdalocollicular projection may modulate therelative activity among several parallel pathways with dedicatedfunctions. Pallid bats use high-frequency echolocation channelsfor general orientation and low-frequency passive listening forprey detection and localization (Bell, 1982; Fuzessery et al.,1993). Different regions of the IC exhibit specializations forprocessing signals associated with these two functions (Fuzessery,1994, 1997). Both receive projections from the amygdala, and theiractivity may be modulated in a context-dependentmanner.

Input from the amygdala may also bias auditory responses within a single processing channel that serves more than one function.In the mustached bat, the frequency range of biosonar signalsoverlaps extensively with the frequency range of social vocalizations(Kanwal et al., 1994). The same specialized IC neurons may analyzeboth types of vocal signals (Portfors and Wenstrup, 2001b), andthis is clearly the case in auditory cortex (Ohlemiller et al.,1996). Similarly, in the pallid bat, pathways serving echolocationand passive listening merge in a population of cortical neurons,with each channel imposing its response properties onto singlecortical neurons (Razak et al., 1999). These neurons can thusparticipate in either function. Perhaps the amygdala alters theresponsiveness of collicular neurons, and consequently corticalneurons, to one or the other of these types of stimuli on thebasis of an animal's behavioral-emotional state. Both forms ofthe modulation by the amygdalocollicular projection could functionin a wide range of mammalian species, particularly those thatdepend on multiple, highly developed acoustic behaviors, includingvocal signaling in social communication or sonar, sound localization,and preydetection.

Why the amygdala intervenes in auditory processing at the midbrain level remains unclear, given that the auditory cortex iscapable of modulating its own input and is in turn modulated bythe amygdala. However, it may be significant that many forms ofresponse selectivity for species-specific sounds originate inthe IC (Fuzessery and Hall, 1996, 1999; Portfors and Wenstrup,2001a; Wenstrup and Leroy, 2001). Perhaps the associative emotional-appetitivecontent from the amygdala plays a role in theircreation.

  FOOTNOTES

Received June 21, 2002; revised Sept. 9, 2002; accepted Sept. 12, 2002.

This work was supported by research grants R01 DC 00937 (J.J.W.) and RO1 DC 00054 (Z.M.F.) from the National Institute onDeafness and Other Communication Disorders, National Institutesof Health and IBN-9828599 (Z.M.F.) from the National Science Foundation.We thank D. Gans, S. Leroy, D. Mittmann, and C. Portfors for helpon some experiments, C. Block for discussions about the amygdala,F.-M. Chen and D. Gans for software, and the Wildlife Sectionof the Ministry of Agriculture, Land and Marine Resources of Trinidadand Tobago for permission to export mustachedbats.

Correspondence should be addressed to Dr. Jeffrey J. Wenstrup, Department of Neurobiology and Pharmacology, Northeastern OhioUniversities College of Medicine, 4209 State Route 44, Rootstown,OH 44272-0095. E-mail: jjw{at}neoucom.edu.

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