Organization of Corticostriatal and Corticoamygdalar Projections Arising from the Anterior Inferotemporal Area TE of the Macaque Monkey: A Phaseolus vulgaris Leucoagglutinin Study

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Volume 17, Number 20, Issue of October 15, 1997 pp. 7902-7925
Copyright ©1997 Society for Neuroscience

Organization of Corticostriatal and Corticoamygdalar Projections Arising from the Anterior Inferotemporal Area TE of the Macaque Monkey: A Phaseolus vulgaris Leucoagglutinin Study

K. Cheng, K. S. Saleem, and K. Tanaka
The Institute of Physical and Chemical Research (RIKEN), Wako, Saitama 351-01, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Corticostriatal and corticoamygdalar projections arising from area TE of the macaque monkey were studied by focal injectionsof the anterograde tracer Phaseolus vulgaris leucoagglutinin intothe dorsolateral and ventromedial subdivisions of the anteriorTE (TEad and TEav, respectively). This approach yielded severalnew results. First, the global distributions of labeled terminalsrevealed that both TEad and TEav projected to the ventrocaudalstriatum, including the tail of the caudate nucleus and the adjacentventral putamen, and the dorsolateral aspect of the deep amygdaloidnuclei. TEav also projected to the medial basal nucleus of theamygdala and the ventral striatum. Second, the reconstructed singleaxons (n = 18) demonstrated that some axons originating from TEavor TEad projected simultaneously to the ventrocaudal striatumand the dorsolateral aspect of the deep amygdaloid nuclei by givingoff collaterals. TEav axons projected to the medial basal nucleusof the amygdala also had collaterals projecting to the perirhinalcortex or area TG. And third, it was revealed that the axons originatingfrom a focal TEav or TEad projected to a restricted territory(3.4-3.6 mm rostrocaudally) in the ventrocaudal striatum withfour to six dispersed, rostrocaudally elongated, rod-like modules.Individual axons with multiple arbors innervated many of thesemodules. These findings add the evidence that the anterior partof TE is anatomically heterogeneous and suggest that the deepamygdaloid nuclei may be functionally dissociated, with the dorsolateralaspect more closely related to the ventrocaudal striatum and themedial basal nucleus more closely related to the perirhinal cortex.
Key words: macaque monkey; inferotemporal cortex; area TE; column; striatum; amygdala; perirhinal cortex; corticostriatal projection; corticoamygdalar projection; PHA-L; single axon; axon collaterals; arbor

INTRODUCTION

Area TE of the inferotemporal cortex of the macaque monkey is crucial for recognition and discrimination of visual imagesof objects (for review, see Gross, 1973; Dean, 1976). Neuronsin TE selectively respond to complex visual features, and TE neuronswith similar stimulus selectivity cluster in columnar regions(for review, see Tanaka, 1993, 1996). TE projects to several polysensoryareas, including the perirhinal cortex, striatum, and amygdala.The projections from the anterior part of TE to the striatum andamygdala were analyzed in the present study.

The striatum receives projections from visual and sensorimotor areas and sends outputs to the pallidum and substantia nigra,which in turn project to the thalamus and then to motor areasof the frontal cortex. This cortico-basal ganglia-thalamo-corticalloop is thought to integrate visual or sensorimotor informationwith behavioral significance and to influence motor output (forreview, see Parent and Hazrati, 1995). The amygdala receives highlyprocessed sensory information from all sensory modalities andin turn projects to the hypothalamus, thalamus, striatum, andhippocampal formation (for review, see Amaral et al., 1992) andis thought to be crucial in certain forms of associative and emotionalmemories (for review, see Gaffan, 1992; LeDoux, 1992; Gallagherand Chiba, 1996).

Previous studies have described the projections from TE to the striatum and amygdala (Whitlock and Nauta, 1956; Jones andPowell, 1970; Kemp and Powell, 1970; Herzog and Van Hoesen, 1976;Yeterian and Van Hoesen, 1978; Aggleton et al., 1980; Turner etal., 1980; Van Hoesen et al., 1981; Iwai and Yukie, 1987; Iwaiet al., 1987; Saint-Cyr et al., 1990; Webster et al., 1991, 1993;Baizer et al., 1993), but these descriptions were limited to theglobal features of the projections. In the present study, we usedfocal injections of Phaseolus vulgaris leucoagglutinin (PHA-L)to elucidate the following three aspects of the projections. First,because it has been suggested that the anterior part of TE isa heterogeneous area that is composed of dorsolateral (TEad) andventromedial (TEav) divisions based on anatomical (Yukie et al.,1992; Saleem et al., 1995; Saleem and Tanaka, 1996) and inactivation(for review, see Horel, 1996) studies, we compared the projectionsfrom anatomically defined TEad and TEav to the striatum and amygdala.Second, because the columnar organization has been shown in TE(for review, see Tanaka, 1993, 1996), we analyzed projection patternsfrom a small area in TEad and TEav by localizing the injectionsite to a size comparable to that of TE columns (Fujita et al.,1992). Finally, and most importantly, focal injections of PHA-Lmade it possible to trace single corticostriatal and corticoamygdalaraxons. Information about branching and arborizing patterns ofsingle axons, which has been lacking because of technical limitation(cf. DiFiglia et al., 1978), is of special value for understandingbetter the functional organization of corticostriatal and corticoamygdalarsystems. The results from reconstructed single axons were emphasizedin the present study.

Some of the present results have appeared elsewhere in abstract form (Cheng et al., 1993).

MATERIALS AND METHODS
Four Japanese monkeys (Macaca fuscata), weighing between 3.3 and 4.6 kg, were used. A single PHA-L injection was made in TEadof the right hemisphere of two monkeys and in TEav of the righthemisphere of the other two monkeys. Three of these four PHA-Lcases were also used in another study conducted in this laboratory(Saleem and Tanaka, 1996).

Surgery and injection. The methods for surgery and injection have been described in detail by Saleem et al. (1993) and Saleemand Tanaka (1996). Briefly, PHA-L was delivered during asepticsurgery under general anesthesia. After an initial introductionof atropine sulfate (0.1 mg/kg, i.m.), the monkey was anesthetizedwith ketamine hydrochloride (12 mg/kg, i.m.), followed by intraperitonealinjection of sodium pentobarbital (Nembutal, 35 mg/kg). Tranexamicacid (25 mg/kg, i.m.) was administered to minimize bleeding. Supplementaldoses of sodium pentobarbital (9 mg/kg, i.p.) were injected whennecessary to maintain the surgical level of anesthesia.

After a large craniotomy was made over the temporal area, the dura was cut to expose a large extent of the superior temporalsulcus and the anterior middle temporal sulcus for determiningthe site of PHA-L injection. To reduce the brain volume and tofacilitate access to the cortex medial to the anterior middletemporal sulcus, 20 ml of mannitol (20%) was intravenously injectedin the two TEav cases. PHA-L (2.5%; Vector Laboratories, Burlingame,CA) was injected iontophoretically (Midgard precision currentsource; Stoelting), according to the procedure recommended byGerfen and Sawchenko (1984) with some modifications (Saleem etal. 1993). After the injection of PHA-L was completed, the durawas sutured, and the wound was closed. The antibiotic piperacillinsodium (55 mg/kg, i.m.) and the analgesic ketoprofen (5 mg/kg,i.m.) were injected daily for 4-5 d after the surgery.

Perfusion and histology. After 16-18 d of postinjection survival, the monkey was lethally anesthetized with sodium pentobarbitaland perfused through the heart with 1 l of 0.9% warm heparinizedsaline and then 3-4 l of 4% paraformaldehyde in 0.1 M phosphatebuffer, pH 7.2-7.4, 1-2 l of 10% sucrose in 0.1 M phosphate buffer,and finally 1 l of 20% sucrose in 0.1 M phosphate buffer. Thebrain was removed immediately after the perfusion, photographed,blocked, and then put in 30% buffered sucrose at 4°C until itsank. Frozen tissue blocks were sectioned at 30 (case 1, TEad),35 (case 2, TEad), and 40 (cases 3 and 4, TEav) µm thickness inthe coronal plane. All sections were processed for PHA-L, andsome of the PHA-L sections were counterstained for Nissl afterthe PHA-L analysis was completed, to facilitate demarcation ofthe borders of the cortical areas and layers and the amygdaloidnuclei. Transported PHA-L was visualized by an avidin-biotin immunoperoxidasemethod described by Saleem et al. (1993).

Data analysis. All sections were first globally analyzed for the extent of labeled terminals in the striatum, the amygdala,and the claustrum. The outlines of these structures and labeledterminals for selected sections were drawn with the aid of a camera-lucidamicroscope attachment (20× or 40× magnification for structureoutlines, and 100× magnification for labeled terminals). The intervalbetween adjacent selected sections varied between cases and structures,ranging from 300 to 700 µm. The PHA-L-treated sections exhibitedsubstantial shrinkage of at least 25% in the mediolateral anddorsoventral dimensions on a coronal section (Rockland et al.,1994). In the present study, the rostrocaudal extent was calculatedbased on the thickness of frozen sections. The shrinkage in thetwo dimensions on coronal sections was not corrected.

The global observation of the labeling also aided in the reconstruction of single axons by facilitating the localization ofpatches or clusters of terminals and axonal trunks well filledwith PHA-L in the gray matter. A single axon was followed, usingthe camera-lucida microscope attachment, through serial sectionsat 200× magnification, usually starting from a segment of an axonaltrunk in the vicinity of a terminal cluster in the striatum orthe amygdala. From this segment, the axonal trunk was traced totwo other extremes of the axon. These were distal portions ofthe axon with terminal specializations, that is, the varicoseor stalked profile of terminal collaterals and the proximal portionof the axon entering the white matter, which in most cases couldbe traced back to the injection site. For all reconstructed axons,a variable number of branches were encountered during the courseof the reconstruction. Each branch was then traced independently.When an axon was being traced, proximal segments of other axonsin the vicinity were simultaneously traced to provide reliablelandmarks for matching the axon between adjacent sections. Ifsuch nearby axons were not available, other landmarks such asblood vessels were used for the purpose of alignment. Terminalarbors were traced with morphological details such as varicositiesand terminal swellings, presumably synaptic boutons, at a highermagnification (400×). The majority of terminals in an arbor weretraced to their ends, but some terminals became too faint to befollowed, and in some rare cases, blind ending processes wereencountered. The exact extent of an arbor, thus, may have beenslightly underestimated, but no axonal branches appear to havebeen missed unless otherwise noted. Although all arbors (if possible)of an axon were traced with varicosities and terminal swellings,we did not focus our analysis in the present study on these morphologicaldetails.

Nomenclature of amygdaloid nuclei and cortical regions. Most of the subcortical structures including the amygdaloid nucleiwere readily distinguishable in PHA-L sections under Nomarskyoptics. Subdivisions of the amygdaloid nuclei described by Amaralet al. (1992) were adopted with some modifications. The basalnucleus was divided into the lateral basal nucleus (correspondingto the magnocellular and intermediate divisions of the basal nucleusof Amaral et al., 1992) and the medial basal nucleus (correspondingto the parvicellular division of the basal nucleus) on the groundsthat the projections from TEav and TEad to these two nuclei appearedto be organized very differently (see Results). The periamygdaloidcortex, the central nucleus, and the accessory basal nucleus werenot further subdivided, because there were no or only faintlylabeled terminals in these subnuclei. The paralaminar nucleus,a very thin nucleus immediately ventral to the medial basal nucleus(Amaral et al., 1992), was identifiable but is not illustratedin the figures in the present study. The cytoarchitectonic bordersbetween TEad and TEav and between TEav and the perirhinal cortexare based on the results of Saleem and Tanaka (1996).

RESULTS
After a brief description of PHA-L injection sites and general labeling features of axonal fibers and terminals, the resultswill be presented in three sections. The global distributionsof terminal fields, with emphases on similarities and differencesbetween projections from TEav and TEad to the striatum and theamygdala, will be described in the first section. Detailed patternsof projections from TEav and TEad to the striatum and the amygdala,based on serially reconstructed single axons, will then be presentedin the second section. Finally, in the third section, the organizationof corticostriatal projections from a focal injection in TEavor TEad will be investigated by comparing terminal arborizationsof single axons with the global distributions of labeled terminals.

Injection sites and general features of PHA-L labeling
PHA-L injections in the two TEad cases were made in the cortex between the ventral lip of the superior temporal sulcus andthe lateral lip of the anterior middle temporal sulcus and inthe two TEav cases in the cortex just medial to the medial lipof the anterior middle temporal sulcus (Fig. 1A-C). The injectionsites measured from 0.5 to 1.0 mm in diameter in the plane parallelto the pial surface and involved all cortical layers in threecases (cases 1, 3, and 4; see Fig. 1B,C) and the lower part oflayer III through layer VI in the fourth case (case 2). All injectionsites were well localized within TEad or TEav (Saleem and Tanaka,1996).
Fig. 1. PHA-L injection sites and labeling of axonal fibers in the white matter. A, Schematic brain diagrams illustrating PHA-L injectionsites (filled circles) in the two TEad cases (Case 1 and Case2, lateral view) and the two TEav cases (Case 3 and Case 4, bottomview). B, C, Photomicrographs showing PHA-L injection sites incoronal sections in a TEad case (B, case 1) and a TEav case (C,case 3). The two sections were counterstained for Nissl to identifythe cortical layers. D, Camera-lucida drawing of a coronal sectionfrom case 4. PHA-L-labeled axonal fibers in the white matter circumscribedby the shaded rectangle are shown at higher magnification by aphotomicrograph (bottom panel). The two arrows indicate an axonaltrunk that courses dorsally and terminates in the ventral putamen.The complete reconstruction of this axon (axon 4-1) is shown inFigure 15. The bundles of fibers on the right run dorsally androstrally toward more rostrally located subcortical structuresor cortical areas. amt, Anterior middle temporal sulcus; ot, occipitotemporalsulcus; pmt, posterior middle temporal sulcus; st, superior temporalsulcus; rh, rhinal sulcus; Amy, amygdala; Cd, caudate nucleus;Cl, claustrum; H, hippocampus; LV, lateral ventricle; Put, putamen.The same abbreviations for sulci are used in all figures unlessotherwise stated. Scale bars: B, C, 1 mm; D, 0.2 mm.
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Axonal branches and terminals in the gray matter in all cases were thoroughly filled with PHA-L, allowing us to visualizemorphological details such as varicosities and terminal swellings(see Fig. 8B). Axonal trunks in the white matter were also satisfactorilylabeled, and in most cases they could be traced back to the injectionsite. In addition, axonal fibers that projected to different subcorticalstructures or cortical areas were usually grouped together indifferent bundles and could be easily differentiated in serialcoronal sections (Fig. 1D).
Fig. 8. Photomicrographs showing axonal fibers and terminals labeled after PHA-L injection into TEav (case 4). Four sections (113,131, 147, 191) are illustrated at both low (left column) and high(right column) magnifications. Arrows in each pair of photomicrographsindicate identical locations. A, B, Proximal axonal trunk andan emerging branch (arrow) of axon 4-2 in the ventral putamen(for complete details, see Figs. 7, ar3, 9B). Note the differencesin thickness and morphology between the smooth proximal axonaland the beaded branch with terminal swellings and varicosities(arrowheads in B). C, D, Distinctive terminal cluster in the ventralputamen, in which two arbors of two different axons were reconstructed(axon 4-2, Figs. 7, 9E, ar8; axon 4-1, Fig. 15, ar6). The arrowsindicate an emerging branch (of axon 4-1) coursing toward thedensest part of the cluster. E, F, Arbor ar7 of axon 4-2 (Figs.7, 9D) in the ventral putamen. G, H, Circumscribed terminal clusterwithin the lateral nucleus (L) of the amygdala. Arbor 10 of axon4-2 (Figs. 7, 9F) was completely reconstructed in this cluster.L, Lateral nucleus of the amygdala; Put, putamen; WM, white matter.Scale bars: A, C, E, G, 100 µm; B, D, F, H, 50 µm.
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Global distributions of labeled terminals: TEav versus TEad
Projections to the striatum As shown in Figure 2 for case 3, labeled terminals formed two separate dense zones in the striatum after TEav injections:one in the lateral aspect of the ventrocaudal striatum composedof the tail of the caudate nucleus and the adjacent ventral putamen(Fig. 2A-D), and the other in the ventral striatum composed ofthe nucleus accumbens, the olfactory tubercle, and the adjacentventral part of the head of the caudate nucleus and the ventralputamen (Fig. 2G-I). The two terminal zones were separated fromeach other at the level of the anterior commissure (Fig. 2E,F).In addition, some sparsely distributed terminals were seen morerostrally in the dorsolateral part of the head of the caudatenucleus and the lateral part of the ventral putamen (Fig. 2H-N).The distributions of labeled terminals in the other TEav case(case 4; data not shown) were very similar to those observed incase 3.
Fig. 2. Camera-lucida drawings of 13 coronal section outlines showing the distribution of PHA-L-labeled terminals in the ventrocaudalstriatum (composed of the tail of the caudate nucleus and adjacentventral putamen), the ventral striatum (composed of the nucleusaccumbens, olfactory tubercle, and adjacent ventral part of thehead of the caudate nucleus and ventral putamen), and the remainingparts of the striatum after TEav injection (case 3). Numbers indicateserial numbers of individual sections (40 µm thick); bottom sectionnumbers indicate posterior sections. Section outlines are illustratedcaudorostrally (A-N) at equal intervals (1.2 mm). Note the absenceof labeled terminals at the level of the anterior commissure (E,F). AC, Anterior commissure; Cd, caudate nucleus; IC, internalcapsule; NA, nucleus accumbens; OT, olfactory tubercle; Put, putamen.
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As shown for case 3 in Figure 2A-D, the labeled terminals in the ventrocaudal striatum were distributed within a restrictedtotal territory, which measured ~2.1 mm (2.2 mm in case 4) mediolaterally(ML), 4.2 mm (3.9 mm) dorsoventrally (DV), and 3.5 mm (3.4 mm)rostrocaudally (RC). The rostrocaudal extent of terminal fieldsin the ventral striatum was limited to ~3.0 mm in both cases,but the labeled terminals covered almost the full mediolateraland dorsoventral extents of the ventral striatum. In both theventrocaudal striatum and ventral striatum, the labeled terminalswere not evenly distributed within the total territory, but theyformed several distinctive patches in any given section.

Injections into TEad resulted in similar distinctive patchy terminal fields in the ventrocaudal striatum, whereas there wereno labeled terminals in the ventral striatum or other portionsof the striatum. The distribution of labeled terminals for case1 is illustrated in Figure 3, but a very similar projection patternwas observed in case 2 (see Fig. 11). Compared with the terminalfields of TEav projections, the terminal fields in the TEad caseswere slightly more sparse but were distributed within a restrictedterritory of comparable size (1.8 mm ML × 4.7 mm DV × 3.6 mm RCin case 1 and 2.6 mm × 3.5 mm × 3.5 mm in case 2). It should benoted that the terminal fields in the ventrocaudal striatum inall four cases were very similar with respect to their RC extents(3.4-3.6 mm).
Fig. 3. Camera-lucida drawings of 7 coronal section outlines showing the distribution of PHA-L-labeled terminals in the ventrocaudalstriatum after TEad injection (case 1). Numbers indicate serialnumbers of individual sections (30 µm thick); bottom section numbersindicate posterior sections. Section outlines are illustratedcaudorostrally (A-G) at equal intervals (0.6 mm). Abbreviationsare the same as in Figure 2.
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Fig. 11. Camera-lucida reconstruction of axon 2-1 labeled by PHA-L anterogradely transported from TEad (case 2) to the ventrocaudalstriatum and the dorsolateral aspect of the deep amygdaloid nuclei.This axon was serially reconstructed through 79 sections (sectionthickness, 35 µm). Abbreviations and conventions are the sameas in Figure 7.
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The measurements of the terminal fields in the ML and DV directions after TEav or TEad injections were comparable to thosedescribed for the corticostriatal projections based on large injectionsin TE, but the RC extents were much shorter than those in theprevious studies [cf. 13 mm (Saint-Cyr et al., 1990, measuredfrom their Fig. 11A), 16 mm (Baizer et al., 1993, their Fig. 6B),and 9 mm (Webster et al., 1993, their Fig. 7)]. The differencein the RC extent between our cases and these previous studiesmay be attributable to the size and location of injection sites;their injections were much larger than ours and involved boththe anterior and posterior portions of the dorsal TE.
Projections to the amygdala The terminal fields in the amygdala formed two zones in both TEav cases, as illustrated in Figure 4 for case 3. In one zone,labeled terminals were mostly distributed in the lateral basalnucleus and the dorsomedial aspect of the lateral nucleus. Halfwayinto the amygdaloid complex, some sparsely but definitely labeledterminals extended into the dorsolateral aspect of the accessorybasal nucleus (Fig. 4F). The labeled terminals in the accessorybasal nucleus were denser and extended more medially in case 4(see Figs. 10, 12) than in case 3. This projection zone is referredto as the dorsolateral aspect of the deep amygdaloid nuclei inthe present study.
Fig. 4. Camera-lucida drawings of 8 coronal section outlines showing the distribution of PHA-L-labeled terminals in the amygdala afterTEav injection (case 3). Numbers indicate serial numbers of individualsections (40 µm thick); bottom section numbers indicate posteriorsections. Section outlines are illustrated caudorostrally (A-H)at equal intervals (0.6 mm). AAA, Anterior amygdaloid area; AB,accessory basal nucleus; CE, central nucleus; COa, anterior corticalnucleus; En, endopiriform nucleus; L, lateral nucleus; LB, lateralbasal nucleus; M, medial nucleus; MB, medial basal nucleus; NLOT,nucleus of the lateral olfactory tract; PAC, periamygdaloid cortex;Pir, piriform cortex; DAN, deep amygdaloid nuclei; Cd, caudatenucleus; Cl, claustrum; EC, entorhinal cortex; H, hippocampus;LV, lateral ventricle; Put, putamen; rh, rhinal sulcus.
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Fig. 10. Camera-lucida reconstruction of axon 4-3 labeled by PHA-L anterogradely transported from TEav (case 4) to the ventrocaudalstriatum and the dorsolateral aspect of the deep amygdaloid nuclei.This axon was serially reconstructed through 177 sections (sectionthickness, 40 µm). AC, Anterior commissure. Other abbreviationsand conventions are the same as in Figure 7.
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Fig. 12. Camera-lucida reconstruction of axon 4-4 labeled by PHA-L anterogradely transported from TEav (case 4) to the medial basalnucleus (MB) of the amygdala and the perirhinal cortex (area 36).This axon was serially reconstructed through 92 sections (sectionthickness, 40 µm). Note that the branch terminating in the medialbasal nucleus does not encroach into other deep amygdaloid nuclei.35, Area 35; 36r, rostral division of area 36; amt, anterior middletemporal sulcus. Other abbreviations and conventions are the sameas in Figure 7.
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The terminal fields in the dorsolateral aspect of the deep amygdaloid nuclei after TEav injections are not composed of distinctivepatches, although the labeled terminals are not evenly distributedover the terminal fields (Fig. 4). A prominent characteristicof the TEav projections to the dorsolateral aspect of the deepamygdaloid nuclei was their large coverage of the rostrocaudalextent of the deep amygdaloid nuclei. The terminal field coveredthe rostral 80% in case 4 and the rostral 70% in case 3 of thetotal extent of the amygdala (4.2 of 5.4 and 3.6 of 5.2 mm, respectively).In addition, in both TEav cases, the terminal fields in the dorsolateralaspect of the deep amygdaloid nuclei shifted ventrally towardmore rostral levels (Fig. 4).

The second zone of the terminal fields of TEav projections was located in the rostral half of the medial basal nucleus inboth TEav cases (see Figs. 4, 10, 12). Compared with those in thedorsolateral aspect of the deep amygdaloid nuclei, the terminalfields in the medial basal nucleus were more restricted in theirrostrocaudal and mediolateral extents. Both rostrocaudally andmediolaterally, they covered about half of the total extent ofthe nucleus (2.0 mm ML and 2.5 mm RC in both cases). The terminalfields covered the entire dorsoventral extent of the medial basalnucleus from its ventral extreme to its border with the lateralbasal nucleus.

It should be pointed out that labeled terminals in the medial basal nucleus remained separated from those in the dorsolateralaspect of the deep amygdaloid nuclei throughout their entire rostrocaudalextents. We shall describe this separation more thoroughly inthe next section, because the reconstructed single axons havedemonstrated that the projection originating from TEav to themedial basal nucleus is different from that to the dorsolateralaspect of the deep amygdaloid nuclei.

In both TEav cases, no labeled terminals were observed in the central nucleus or any of the superficial amygdaloid nuclei.

After injections into TEad, labeled terminals were found only in the dorsolateral aspect of the deep amygdaloid nuclei. Nolabeled terminals were observed in the medial basal nucleus. Comparedwith the terminal fields of the projections in the two TEav cases,those from TEad appeared to be much more sparse and were distributedmore laterally, mostly in the lateral nucleus, and to a lesserextent in the lateral basal nucleus (case 2, Fig. 5). There wasno labeling in the accessory basal nucleus. The rostrocaudal extentsof the terminal fields were also limited to about 25% (case 1)and 55% (case 2) of the total extent of the deep amygdaloid nuclei(1.2 of 5.0 and 2.8 of 5.3 mm, respectively).
Fig. 5. Camera-lucida drawings of 6 coronal section outlines showing the distribution of PHA-L-labeled terminals in the amygdala afterTEad injection (case 2). Numbers indicate serial numbers of individualsections (35 µm thick); bottom section numbers indicate posteriorsections. Section outlines are illustrated caudorostrally (A-F)at equal intervals (0.7 mm). Note the absence of labeled terminalsin the medial basal nucleus (MB). AC, Anterior commissure; BNM,basal nucleus of Meynert. Other abbreviations are the same asin Figure 4.
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Projections to the claustrum In close proximity to the terminal fields in the amygdala, the projections from both TEav and TEad to the claustrum were observed.Labeled terminals were densely distributed in the ventromedialextreme of the claustrum in all four cases. There were no apparentdifferences in the density and distribution of the terminal fieldsbetween TEav and TEad cases (Figs. 4, 5). The rostrocaudal extentsof labeled terminals in the claustrum measured ~2.0 mm in allcases, and in each case, the terminal field in the claustrum appearedat about the same rostrocaudal level as that where labeled terminalsin the dorsolateral aspect of the amygdala were distributed (Figs.4D-G, 5B-E).

The observation that TEav and TEad projected equally well to the claustrum provided further evidence that differences in thestrength and distribution of projections from TEav and TEad tothe striatum and amygdala were not attributable to the differencein the size of the injection or the labeling quality between TEavand TEad cases. The similarity or difference in the internal representationbetween TEav and TEad remains to be elucidated, but the sizesof TEav and TEad are not very different [the ratio of the arealextent of TEav to that of TEad was estimated as ~55:45; also seethe unfolded maps of TEav and TEad injections by Saleem and Tanaka(1996, their Figs. 7, 8)]. Thus, it is our contention that theapparent difference in the amount of coverage of the rostrocaudalextent of the dorsolateral aspect of the deep amygdaloid nucleibetween TEav and TEad injections are genuine properties of corticoamygdalarprojections arising from different subdivisions within the anteriorpart of TE.

Projection patterns of the reconstructed single axons
The projection patterns of individual axons described in the present study are based on 18 axons with collaterals and arborizationswithin the striatum and/or the amygdala that were nearly completelyreconstructed (referred to as completely reconstructed axons).Thirteen of the 18 axons were reconstructed from the TEav cases,and the remaining five were reconstructed from the TEad cases.We reconstructed more single axons from the TEav cases becausethe branching patterns of TEav axons displayed more variety, andTEad axons showed only a fraction of the variety of TEav axons.In addition, six TEav axons were partially reconstructed to verifythe branching patterns of certain axons (referred to as partiallyreconstructed axons). Figure 6 summarizes the projections of singleaxons from TEav and TEad to the striatum and amygdala based onbranching patterns of axon collaterals, including (1) TEav andTEad axons projecting to both the ventrocaudal striatum and thedorsolateral aspect of the deep amygdaloid nuclei, (2) TEav axonsprojecting to both the medial basal nucleus of the amygdala andcortex (perirhinal cortex or area TG), and (3) TEav or TEad axonsprojecting only to the dorsolateral aspect of the deep amygdaloidnuclei, the ventrocaudal striatum, or the ventral striatum. Afew axons had collaterals projecting further to other structuresbut were not investigated in the present study. The detailed projectionpatterns of these individually reconstructed axons are describedbelow.
Fig. 6. Schematic diagrams showing the projections of single axons from TEav (A) and TEad (B) to the striatum and amygdala. The shadedareas in the amygdala indicate the relative locations of the projectionsto the lateral nucleus, lateral basal nucleus, and accessory basalnucleus, which are regarded as single projection zones (dorsolateralaspect of the deep amygdaloid nuclei) and are distinguished fromthe medial basal nucleus (see Results). Arrows with bifurcatingbranches indicate axons with collaterals that terminate in twoor more subcortical structures or cortical areas. Other arrowsshow axons that arborize within a single subcortical structureor cortical area. Shaded arrows show the projections from TEavand TEad to the perirhinal cortex (areas 35 and 36) and area TG,which have been described in detail in another paper (Saleem andTanaka, 1996). Those axon collaterals that project further toother structures are not shown (see Results). AB, Accessory basalnucleus; CE, central nucleus; L, lateral nucleus; LB, lateralbasal nucleus; MB, medial basal nucleus; 35/36, areas 35 and 36of the perirhinal cortex; TG, area TG.
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Dual projection of TEav and TEad axons to the ventrocaudal striatum and amygdala Figure 7 shows an axon reconstructed from a TEav case (axon 4-2). After leaving the injection site, the axon enters the whitematter, where it follows a course lateral to the lateral ventricleand heads toward the ventrocaudal striatum. On entering the ventralputamen, the main axonal trunk bifurcates (Fig. 7, arrow at section129) and then gives off four collaterals (Fig. 7, arrows at sections107 and 113). Two collaterals divide further to form multipleterminal arbors in the tail of the caudate nucleus and the ventralputamen (Fig. 7, ar1-ar9). Some of these arbors are richly ramifiedand result in highly complex plexuses (Fig. 7, ar1, ar6, ar7),whereas the others are poorly ramified. The axonal fibers in theventrocaudal striatum have a smooth appearance, whereas the labeledterminals display varied degrees of varicosities and terminalswellings, presumably the synaptic boutons (Figs. 8B,D,F, 9A-E).These morphological details, however, were not described furtherhere. The third collateral turns medially and courses rostrallyand ventrally toward the medial aspect of the ventrocaudal striatum.After traveling briefly in the white matter between the ventralputamen and the dorsolateral aspect of the amygdala, it entersthe dorsal part of the lateral nucleus of the amygdala. As thecollateral runs through the lateral nucleus caudorostrally, itremains devoid of terminations for a few hundred micrometers.Then, unlike axon collaterals in the ventrocaudal striatum, itemits boutons en passant along its course and finally developsinto a highly beaded terminal plexus within the lateral nucleus(Fig. 7, ar10; also see Figs. 8G,H, 9F). The fourth collateralcourses dorsoposteriorly and medially, traversing the ventralputamen and both the external and internal segments of the pallidum.We were unable to reconstruct this collateral fully, because itruns beyond the most posterior section cut in this case. Presumably,it projects to the thalamic nuclei or even below the thalamiclevel.
Fig. 7. Camera-lucida reconstruction of axon 4-2 labeled by PHA-L anterogradely transported from TEav (case 4) to the ventrocaudalstriatum and the dorsolateral aspect of the deep amygdaloid nuclei.Thick lines represent the main axonal trunk and collaterals, andthin lines represent terminal arbors. Numbers indicate serialnumbers of individual sections; smaller numbers are posterior.This axon was serially reconstructed through 103 sections (sectionthickness, 40 µm). Ten terminal arbors (ar1-ar10) were drawn;each arbor is presented with a range of sections (numbers in parentheses),from which the arbor was completely reconstructed. Sections inwhich the axon gives off major collaterals are indicated by sectionnumbers and arrows. Dashed lines (with section numbers) indicateborders between different structures. The global locations ofterminal arbors are illustrated in low-magnification camera-lucidadrawings of selected sections, where terminal clusters containingindividual arbors are circumscribed by shaded ellipses or circles.Double lines indicate the incomplete portion of the axon. Themain axonal trunk in the white matter was followed to the injectionsite. AB, Accessory basal nucleus; CE, central nucleus; L, lateralnucleus; LB, lateral basal nucleus; MB, medial basal nucleus;Amy, amygdala; Cd, caudate nucleus; Cl, claustrum; GPe, externalglobus pallidus; H, hippocampus; LV, lateral ventricle; Put, putamen;WM, white matter; rh, rhinal sulcus. Orientation: M, medial; L,lateral; D, dorsal; V, ventral. The same conventions and abbreviationsare used for illustrating other reconstructed axons unless otherwisenoted.
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Fig. 9. Six completely reconstructed arbors of axon 4-2 (A-F; see Fig. 7 for their global locations). Note the morphological detailsof varicosities and terminal swellings, presumably synaptic boutons.
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Another TEav axon (axon 4-3) that projects to both the ventrocaudal striatum and the dorsolateral aspect of the deep amygdaloidnuclei is shown in Figure 10. Like axon 4-2, axon 4-3 also bifurcatesafter entering the tail of the caudate nucleus (Fig. 10, arrowat section 74). However, unlike axon 4-2, the two branches ofaxon 4-3 only innervate the tail of the caudate nucleus and ventralputamen to a limited extent (Fig. 10, ar1, ar3) but arborize extensivelyin the lateral nucleus and lateral basal nucleus. After enteringthe amygdala, one branch courses caudorostrally and forms a terminalplexus within the lateral nucleus (Fig. 10, ar2). The other branchfollows a relatively straight course that traverses the medialaspect of the lateral nucleus and the lateral basal nucleus, whereit gives off more collaterals (Fig. 10, arrow at section 170) andleaves the majority of terminals, both in the terminal plexusesand en passant along the collaterals (Fig. 10, ar4-ar8). The latterbranch also terminates to a limited extent in the accessory basalnucleus at a more rostral level but clearly spares the medialbasal nucleus. In addition, axon 4-3 differs from axon 4-2 inthat it does not have any collaterals projecting beyond the ventrocaudalstriatum and the amygdala.

The main axonal trunks of two partially reconstructed TEav axons (one from case 3 and the other from case 4) also projectto both the ventrocaudal striatum and the dorsolateral aspectof the deep amygdaloid nuclei. We also reconstructed one TEadaxon that has five arbors in the ventrocaudal striatum and twoarbors in the dorsolateral aspect of the deep amygdaloid nuclei(axon 2-1, Fig. 11).
Dual projection of TEav axons to the amygdala and cortex As has been described in the previous section, labeled terminals in the medial basal nucleus of the amygdala were observedonly after TEav injections. Figure 12 shows a TEav axon that projectsto the medial basal nucleus (axon 4-4). On leaving the injectionsite, the main axonal trunk courses rostrally and medially andenters the white matter, where it gives off two initial branches(Fig. 12, arrow at section 145). One branch travels a short distancein the white matter, enters the cortex again, and forms two terminalarbors (Fig. 12, ar1, ar2) within the rostral portion of the perirhinalcortex (rostral division of area 36; Fig. 12, 36r) (for subdivisionsof the perirhinal cortex, see Saleem and Tanaka, 1996). The terminalsof both arbors are distributed from layer IV through layer I.The other branch continues its course medially and rostrally inthe white matter lateral to the fundus of the rhinal sulcus andgives off two collaterals (Fig. 12, arrows at sections 204 and219), which terminate again within 36r, with terminals extendingacross all the cortical layers (Fig. 12, ar3, ar4). It is of interestto note that except for one arbor, all arbors in 36r (Fig. 12,ar2-ar4) were reconstructed from the same rostrocaudally elongateddense terminal field (the "core region"; see Saleem and Tanaka,1996). The main branch then turns upward, travels in the whitematter around the fundus of the rhinal sulcus, and finally entersthe medial basal nucleus of the amygdala, where it gives off twofurther collaterals that arborize completely within this nucleus(Fig. 12, ar5, ar6).

Figure 13 shows another TEav axon that has a collateral terminating in the medial basal nucleus (axon 4-5). This axon alsobifurcates in the white matter (Fig. 13, arrow at section 184).The branch that projects to the medial basal nucleus follows coursesimilar to that of axon 4-4 and forms two terminal arbors (Fig.13, ar1, ar2) that overlap with those given off by axon 4-4 inthe medial basal nucleus (Figs. 12, 13, compare the camera-lucidadrawings of sections 215 and 230). The other branch gives offtwo collaterals in the white matter (Fig. 13, arrow at section245). One collateral courses rostrally and medially and breaksdown into at least two terminal arbors that extend across allthe cortical layers at different rostrocaudal levels of the perirhinalcortex (Fig. 13, ar5 in 36r, ar6 in the polar division of area36, 36p) (see Saleem and Tanaka, 1996). The remaining finer branchesof this collateral in the perirhinal cortex were not pursued further,because they run into the densely distributed terminal field,which was so dense that single axons could not be reliably reconstructed.The other collateral continues its course rostrally and ventrallyand forms two arbors in the cytoarchitectonic area TG (Fig. 13,ar3, ar4). The terminals of both arbors are confined to the layersIV and III.
Fig. 13. Camera-lucida reconstruction of axon 4-5 labeled by PHA-L anterogradely transported from TEav (case 4) to the medial basalnucleus (MB) of the amygdala, the perirhinal cortex (area 36),and area TG. This axon was serially reconstructed through 166sections (section thickness, 40 µm). Double lines show incompleteportions of the axon. 36p, Polar division of area 36; 36r, rostraldivision of area 36; TG, area TG; st, superior temporal sulcus.Other abbreviations and conventions are the same as in Figure7.
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Four partially reconstructed TEav axons that we started to trace in the medial basal nucleus showed properties similar tothose of the above two axons; they never terminate in the dorsolateralaspect of the deep amygdaloid nuclei, whereas they have collateralsthat form arbors in the perirhinal cortex. Although we did nottrace all the axons that project to the medial basal nucleus,the above evidence strongly suggests that (1) no axons projectto both the dorsolateral aspect of the deep amygdaloid nucleiand the medial basal nucleus; and (2) all axons projecting fromTEav to the medial basal nucleus also have collaterals projectingto the perirhinal cortex and/or area TG.
Other corticostriatal and corticoamygdalar axons arising from TEav and TEad Of the remaining 13 completely reconstructed axons, seven project to the ventrocaudal striatum, four to the dorsolateral aspectof the deep amygdaloid nuclei, and the other two to the ventralstriatum.

Figure 14 shows an axon reconstructed from a TEad case (axon 1-1). Several collaterals of this axon arborize in the tail ofthe caudate nucleus (Fig. 14, ar1, ar2) and the ventral putamen(Fig. 14, ar3-ar6). The main axonal trunk continues its coursedorsomedially and posteriorly, presumably toward the thalamicnuclei. This axon, without bearing any collaterals projectingto the amygdala, otherwise resembles axon 4-2 (Fig. 7) and maybelong to those long-range axons that project beyond the thalamiclevel. Figure 15 illustrates a TEav axon (axon 4-1) reconstructedfrom the same case as axon 4-2 and axon 4-3. Like axon 4-2 andaxon 4-3 (Figs. 7, 10), axon 4-1 also bifurcates after enteringthe ventral putamen and gives off collaterals that arborize withinthe ventral putamen (Fig. 15, ar1-ar6). Five other completely reconstructedaxons, four from the TEav cases and one from one TEad case, alsobranch and arborize completely in the ventrocaudal striatum.
Fig. 14. Camera-lucida reconstruction of axon 1-1 labeled by PHA-L anterogradely transported from TEad (case 1) to the ventrocaudalstriatum. This axon was serially reconstructed through 112 sections(section thickness, 30 µm). Double lines indicate the incompleteportion of the axon. Abbreviations and conventions are the sameas in Figure 7.
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Fig. 15. Camera-lucida reconstruction of axon 4-1 labeled by PHA-L anterogradely transported from TEav (case 4) to the ventrocaudalstriatum. This axon was serially reconstructed through 58 sections(section thickness, 40 µm). Abbreviations and conventions arethe same as in Figure 7.
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We also traced four axons that project exclusively to the dorsolateral aspect of the deep amygdaloid nuclei (two from theTEav cases and two from the TEad cases). Figure 16 shows one suchaxon, reconstructed from a TEav case (axon 3-7). The axon givesoff two branches just before entering the amygdala (Fig. 16, arrowat section 255). Both branches then run a long distance caudorostrallywithin the amygdala and give off seven arbors in the lateral nucleusand the lateral basal nucleus. Figure 17 shows a TEad axon (axon2-2) that arborizes mostly in the lateral nucleus and the lateralbasal nucleus of the amygdala but has an arbor in the basal nucleusof Meynert (Fig. 17, ar6). In general, the arborization patternsof single axons in the dorsolateral aspect of the deep amygdaloidnuclei were rather different between TEad and TEav: TEad axonsterminated within a limited spatial extent, whereas TEav axonsran along a relatively straight course caudorostrally. This heterogeneityof single axons in their spatial extents may underlie the differencein the caudorostral extents observed for the global distributionsof terminals between TEad and TEav cases.
Fig. 16. Camera-lucida reconstruction of axon 3-7 labeled by PHA-L anterogradely transported from TEav (case 3) to the dorsolateralaspect of the deep amygdaloid nuclei. This axon was serially reconstructedthrough 101 sections (section thickness, 40 µm). Note that althoughthis axon innervates most of the dorsolateral aspect of the deepamygdaloid nuclei, it avoids encroaching into the medial basalnucleus (MB). Abbreviations and conventions are the same as inFigure 7.
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Fig. 17. Camera-lucida reconstruction of axon 2-2 labeled by PHA-L anterogradely transported from TEad (case 2) to the dorsolateralaspect of the deep amygdaloid nuclei and the basal nucleus ofMeynert. This axon was serially reconstructed through 38 sections(section thickness, 35 µm). BNM, Basal nucleus of Meynert. Otherabbreviations and conventions are the same as in Figure 7.
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Two TEav axons in the ventral striatum were reconstructed. Figure 18 shows one such axon (axon 3-2). The main axonal trunkof this axon, along with that of the other simultaneously tracedaxon, was followed to the injection site. There was no indicationthat these axons bifurcate in the white matter, and their coursesin the white matter are different from those projecting to theventrocaudal striatum. The patchy distribution of terminal plexuses(Fig. 18, see camera-lucida drawings of sections 310, 330, 360)and multiple arbors (Fig. 18, ar1-ar7) of the axon, however, appearto be similar to those of the axons reconstructed in the ventrocaudalstriatum.
Fig. 18. Camera-lucida reconstruction of axon 3-2 labeled by PHA-L anterogradely transported from TEav (case 3) to the ventral striatum.This axon was serially reconstructed through 197 sections (sectionthickness, 40 µm). Cd, Caudate nucleus; IC, internal capsule;NA, nucleus accumbens; OT, olfactory tubercle; Put, putamen. Otherabbreviations and conventions are the same as in Figure 7.
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Corticostriatal projections: global terminal distribution versus single axonal arbors
After a focal injection of PHA-L into either TEav or TEad, labeled terminals in the ventrocaudal striatum were distributedin a restricted territory that measured ~1.8-2.6 mm mediolaterally,3.5-4.7 mm dorsoventrally, and 3.4-3.6 mm rostrocaudally. Thelabeled terminals in the territory are grouped into a small numberof patches in any given coronal section (Figs. 2, 3; also seecamera-lucida drawings of coronal sections in Figs. 7, 10, 14, 15).By examining closely spaced sections it was revealed that thepatches formed rostrocaudally elongated, rod-like modules (referredto as "rods" below). In one TEav case (case 4), as demonstratedin Figure 19A, there were six rods, each of which measured 0.8-2.8mm (mean ± SD, 1.63 ± 0.66 mm) in the rostrocaudal direction and0.4-0.8 mm (0.65 ± 0.15 mm) in diameter in coronal sections. Therewere four rods in another TEav case (case 3) and five (case 1)and four (case 2) rods in the TEad cases.
Fig. 19. Multiple rod-like modules of the terminal field and the distribution of terminal arbors of 3 completely reconstructed axonsin the ventrocaudal striatum after PHA-L injection into TEav (case4). Numbers indicate serial numbers of individual sections (40µm thick); bottom section numbers indicate posterior sections.A, Camera-lucida drawings of 11 coronal section outlines showingaxonal terminals in the ventrocaudal striatum. Each rostrocaudallyelongated rod-like module is illustrated in a different color.Six rods were observed in this case. B, Distribution of terminalarbors of 3 reconstructed axons [axon 4-1 (red), axon 4-2 (green),and axon 4-3 (yellow); see Figs. 7, 10, 15 for details of the 3axons) in the terminal fields identical to those shown in A. Notethat the arbors of the 3 axons innervated 5 of 6 rods, sparingonly 1 rod (shown in brown in A). Cd, Caudate nucleus; Cl, claustrum;Put, putamen.
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The axons that projected to the ventrocaudal striatum were shown to bear multiple terminal arbors. Of the 10 reconstructedaxons that arborized completely or had collaterals arborizingin the ventrocaudal striatum, the number of arbors within theventrocaudal striatum ranged from two (axon 4-3, Fig. 10) to nine(axon 4-2, Fig. 7), with most of the axons having five to sevenarbors (axon 1-1, Fig. 14; axon 4-1, Fig. 15). The complexity oframifications among reconstructed arbors varied greatly (compareFigs. 7, 10, 14, 15). The well ramified arbors of both TEav and TEadaxons (e.g., arbors of axon 4-2 shown in Fig. 9A-E) typicallymeasured 0.4 mm in the minor axis and 0.8 mm in the major axis,whereas other arbors had a relatively simple appearance. Therewas no obvious tendency that individual arbors had any preferredorientations.

Single axons projected to multiple rod-like modules with variable degrees of divergence. Multiple arbors of an axon were usuallysegregated from each other and located in different rods, althoughin some cases more than one arbor of the same axon innervateda single rod at different rostrocaudal levels. For example, axon1-1 innervated all five rods in case 1, and axon 2-1 innervatedall four rods in case 2, whereas axons 4-1, 4-2, and 4-3 innervatedthree, two, and four of the six rods, respectively, in case 4.Because of the limited number of rods, this divergent projectionpattern of single axons also suggests that many single axons projectingfrom a small cortical site converge in a given rod. To demonstratethis convergence, arbors of the three axons reconstructed fromthe same TEav case (axons 4-1, 4-2, and 4-3) are illustrated inFigure 19B to compare their distribution with the distributionof rods shown in Figure 19A. The rod marked by light pink is innervatedby arbors of all the three axons, and the rod marked by blue isinnervated by arbors of two axons (axons 4-1 and 4-2). The arborsof the three axons covered five of the six rods.

The terminal fields in the ventral striatum were also composed of rod-like modules, although they were less clearly separatedfrom each other than those in the ventrocaudal striatum. However,it is obvious that single axons innervated multiple rods, as shownfor one axon in Figure 18.

DISCUSSION

Differential projections from TEad and TEav to the striatum and amygdala
By focal injections of PHA-L, we have shown that TEad and TEav have different projections to the striatum and amygdala. AlthoughTEad and TEav projected similarly to the ventrocaudal striatum,TEav projected additionally to the ventral striatum, to whichTEad did not project. The projections from TEad and TEav to thedorsolateral aspect of the deep amygdaloid nuclei were differentin their densities and topographic arrangements; the projectionsfrom TEav were more extensive than those from TEad, and the terminalfield arising from TEav was distributed more medially than thatfrom TEad. Finally, TEav projects to the medial basal nucleus,to which TEad did not project. These results, along with previousfindings that TEad and TEav receive differential afferents fromarea TEO (Desimone et al., 1980; Martin-Elkins and Horel, 1992;Yukie et al., 1992) and send differential efferents to the prefrontalcortex (Saleem et al., 1995) and the perirhinal and entorhinalcortices (Saleem and Tanaka, 1996), indicate that the anteriorpart of TE is anatomically heterogeneous.

The present results regarding the projections from TEad and TEav to the ventrocaudal striatum and the dorsolateral aspectof the deep amygdaloid nuclei are generally consistent with previousresults concerning the striatal and amygdalar projections fromthe middle temporal gyrus and inferior temporal gyrus (ITG) (Whitlockand Nauta, 1956; Jones and Powell, 1970; Kemp and Powell, 1970;Herzog and Van Hoesen, 1976; Van Hoesen et al., 1976, 1981; Yeterianand Van Hoesen, 1978; Aggleton et al., 1980; Turner et al., 1980;Iwai and Yukie, 1987; Iwai et al., 1987; Saint-Cyr et al., 1990;Webster et al., 1991, 1993; Baizer et al., 1993; for review, seeAmaral et al., 1992; Parent and Hazrati, 1995). It has been notedthat the ITG projects to the ventral striatum (Whitlock and Nauta,1956; Van Hoesen et al., 1976, 1981; Yeterian and Van Hoesen;1978) and the medial basal nucleus of the amygdala (Turner etal., 1980; Iwai and Yukie, 1987; Iwai et al., 1987). However,the large ablations or injections in the ITG in these previousstudies appeared to have invaded the ectorhinal cortex, or area36 (Brodmann, 1909), now considered the lateral portion of theperirhinal cortex (Amaral et al., 1987; Insausti et al., 1987;Suzuki and Amaral, 1994a,b; Saleem and Tanaka, 1996). Althoughthe functional dissociation between TEav and the perirhinal cortexis still awaiting elucidation, recent results have shown thatthey are anatomically distinctive. TEav sends feed-forward projectionsto the perirhinal cortex (Suzuki and Amaral, 1994a,b; Saleem andTanaka, 1996), and TEav and the perirhinal cortex project differentiallyto several areas in the medial temporal lobe, including the entorhinalcortex (Van Hoesen and Pandya, 1975; Suzuki and Amaral, 1994a,b;Saleem and Tanaka, 1996) and the hippocampus (Suzuki and Amaral,1990). The present study contributes to our understanding of theprojections from the anatomically defined TEav to the striatumand amygdala. Additional studies are needed to investigate thedifferences between the projections to these two structures fromTEav and the perirhinal cortex, respectively.

Parallel processing of visual cortical information in the striatum and amygdala via axon collaterals
The present study represents the first attempt to elucidate corticostriatal and corticoamygdalar projections in monkeys byreconstructing single axons. We found that some single axons projectto two or more subcortical structures or cortical areas. Theseinclude the axons projecting to the ventrocaudal striatum andthe dorsolateral aspect of the deep amygdaloid nuclei and theaxons projecting to the medial basal nucleus of the amygdala andarea 36 of the perirhinal cortex or area TG. These axons may playfunctionally important roles in synchronizing the activities ofmultiple subcortical or cortical structures to which they feedcommon information from the visual cortex.

Functional dissociation of the deep amygdaloid nuclei
One of the most interesting findings in the present study is that fibers projecting to the medial basal nucleus are collateralsof the axons projecting to the perirhinal cortex or area TG, andthese axons are separated from those projecting to the remainingdeep amygdaloid nuclei. A definite number of the latter axonsalso have collaterals projecting to the ventrocaudal striatum.These findings raise the possibility that the dorsolateral aspectof the deep amygdaloid nuclei, including the lateral nucleus,lateral basal nucleus, and accessory basal nucleus, is functionallymore closely related to the ventrocaudal striatum, whereas themedial basal nucleus is more closely related to the perirhinalcortex.

Other anatomical connections of the deep amygdaloid nuclei support this view. The lateral basal nucleus of the amygdala projectsstrongly to the ventrocaudal striatum (Parent et al., 1983; Russchenet al., 1985). Although most of the deep amygdaloid nuclei havereciprocal connections with the perirhinal cortex, the projectionsto the perirhinal cortex appear to be the strongest from the medialbasal nucleus (Amaral and Price, 1984; Stefanacci et al., 1996).In addition, the medial basal nucleus receives projections fromthe entorhinal cortex (Amaral et al., 1992) and has reciprocalconnections with the subiculum and the CA1 region of the hippocampus(Rosene and Van Hoesen, 1977; Amaral and Cowan, 1980; Amaral,1986; Saunders et al., 1988).

Behavioral studies on lesioned monkeys have indicated different functional roles of the perirhinal cortex and the ventrocaudalstriatum. The perirhinal cortex plays important roles in visualrecognition memory (Meunier et al., 1993; Eacott et al., 1994;Gaffan, 1994; Ramus et al., 1994; Leonard et al., 1995; Tang andAigner, 1996) and certain types of stimulus-stimulus associationmemories (Murray, 1996). The ventrocaudal striatum has been suggestedto be involved in stimulus-response association learning or habitformation (Mishkin et al., 1984; Petri and Mishkin, 1984). A morerecent view suggests that this pathway is generally importantfor the control of action (Gaffan, 1996). Thus, although the amygdalais known to be crucial in relating environmental stimuli to primaryreinforcement (Gaffan, 1992) and emotional memory (LeDoux, 1992;Gallagher and Chiba, 1996), it is possible that the dorsolateralaspect of the deep amygdaloid nuclei is more related to stimulus-responseassociation or habit formation, whereas the medial basal nucleusis more related to stimulus-stimulus association or recognitionmemory.

Organization of the corticostriatal projection
The detailed organization of the corticostriatal projection is of the utmost importance in determining the nature of the informationthat is conveyed and integrated through the cortico-basal ganglia-thalamo-corticalloop (Alexander et al., 1986; Parent and Hazrati, 1995). The patchydistributions of terminal fields have been observed for projectionsfrom other cortical areas to the striatum (Künzle, 1975; Goldmanand Nauta, 1977; Jones et al., 1977; Selemon and Goldman-Rakic,1985; Eblen and Graybiel, 1995), and they are related to the patchmatrix striatal compartmentalizations (Graybiel, 1990; Gerfen,1992; Parent and Hazrati, 1995). However, a consensus on the plausiblefunctional roles of these divergent corticostriatal projectionshas not been established. Some investigators link them to the"parallel processing" in the cortico-basal ganglia-thalamocorticalloop (Alexander et al., 1986; Alexander and Crutcher, 1990), whereasothers favor an "informational funnel hypothesis" (Percheron andFilion, 1991; but see Parent and Hazrati, 1993). To resolve thedifferences in the interpretation of functional roles of divergentcorticostriatal projections, studies at the cellular level areneeded. The few previous studies on the corticostriatal projectionsat the single-cell level have substantially underestimated thecomplexity of divergent arborizations of single axons (Ramóny Cajal, 1911; DiFiglia et al., 1978), which led to the hypothesisthat corticostriatal axons are poorly branched and emit boutonsen passant to make synaptic contacts with striatal neurons alongthe rostrocaudal plane of the striatum (see Parent and Hazrati,1995, their Fig. 2C).

Based on single-unit and optical recording experiments (Fujita et al., 1992; Wang et al., 1996), it is known that cells locatedin a column (equivalent to the size of our injections) in theanterior TE tend to respond to related but not identical visualfeatures of objects. It is proposed that TE cells organized inthis way may underlie the flexible coding of visual features ofobjects, i.e., the toleration of tiny changes in the visual patternscaused by changes in viewing angle, viewing distance, or luminance(Tanaka, 1993, 1996). This invariance, however, requires thatsingle efferent axons from a TE column, which represent slightlydifferent visual features, converge to single cells in the downstream.We showed that the projections from TE to the ventrocaudal striatumhad characteristics consistent with this requirement. Althoughthe projection from a TE column diverges to several rod-like modulesin the ventrocaudal striatum, each of the rod-like modules isinnervated by a large number of axons projecting from the TE column.It is likely that the variations in information represented ina TE column are integrated in each module. We would further suggestthat these modules may form a striatal functional unit. Assumingthat these modules, to which a TE column divergently projects,receive different kinds of information from other sensory corticalareas and the amygdala individually, whereas their outputs convergeonto a single site in the pallidum or the substantia nigra, thefunctional unit will work as machinery for associating visualinformation represented in a cortical column with massive amountsof information from other sources. This may be a general rulefor the organization of corticostriatal projections. Indeed, ina study performed by placing anterograde tracers in the sensorimotorcortex and retrograde tracers in the external and internal pallidalsegments, Flaherty and Graybiel (1994) have shown that dispersedmodules ("matriosomes") in the putamen, which receive projectionsfrom a single site in the sensorimotor cortex, in turn send convergentoutputs to a single site in the pallidum.

FOOTNOTES

Received June 19, 1997; revised Aug. 5, 1997; accepted Aug. 7, 1997.

This work was supported by the Frontier Research Program, The Institute of Physical and Chemical Research (RIKEN), Japan.We thank W. Suzuki and A. H. Asiya Begum for surgical and histologicalassistance and two anonymous reviewers for helpful comments.

Correspondence should be addressed to Dr. K. Cheng, Laboratory for Cognitive Brain Mapping, Brain Science Institute, The Instituteof Physical and Chemical Research (RIKEN), Hirosawa 2-1, Wako,Saitama 351-01, Japan.

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