Synaptic Integration of Functionally Diverse Pallidal Information in the Entopeduncular Nucleus and Subthalamic Nucleus in the Rat

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Volume 17, Number 1, Issue of January 1, 1997 pp. 308-324
Copyright ©1997 Society for Neuroscience

Synaptic Integration of Functionally Diverse Pallidal Information in the Entopeduncular Nucleus and Subthalamic Nucleus in the Rat

Mark D. Bevan, Nick P. Clarke, and J. Paul Bolam
Medical Research Council Anatomical Neuropharmacology Unit and University Department of Pharmacology, Oxford OX1 3TH, United Kingdom

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

To determine the principles of synaptic innervation of neurons in the entopeduncular nucleus and subthalamic nucleus by neuronsof functionally distinct regions of the pallidal complex, doubleanterograde labeling was carried out at both light and electronmicroscopic levels in the rat. Deposits of the anterograde tracersPhaseolus vulgaris-leucoagglutinin and biotinylated dextran aminewere placed in different functional domains of the pallidal complexin the same animals. The tracer deposits in the ventral pallidumand the globus pallidus gave rise to GABA-immunopositive projectionsto the entopeduncular nucleus, the subthalamic nucleus, and themore medial lateral hypothalamus that were largely segregatedbut overlapped at the interface between the two fields of projection.In these regions the proximal parts of individual neurons in theentopeduncular nucleus, lateral hypothalamus, and subthalamicnucleus received synaptic input from terminals derived from boththe ventral pallidum and the globus pallidus. Furthermore, theanalysis of the afferent synaptic input to the dendrites of neuronsin the subthalamic nucleus that cross functional boundaries ofthe nucleus defined by the pallidal inputs, revealed that terminalswith the morphological and neurochemical characteristics of thosederived from the pallidal complex make synaptic contact with allparts of the dendritic tree, including distal regions.
It is concluded that functionally diverse information carried by the descending projections of the pallidal complex is synapticallyintegrated by neurons of the entopeduncular nucleus, lateral hypothalamus,and subthalamic nucleus by two mechanisms. First, neurons locatedat the interface between functionally distinct, but topographicallyadjacent, projections could integrate diverse information by meansof the synaptic convergence at the level of the cell body andproximal dendrites. Second, because the distal dendrites of neuronsin the subthalamic nucleus receive input from the pallidum, thosethat extend across two distinct domains of pallidal input couldalso provide the morphological basis of integration.
Key words: ventral pallidum; globus pallidus; subthalamic nucleus; entopeduncular nucleus; basal ganglia; synaptic convergence

INTRODUCTION

The basal ganglia are a group of subcortical nuclei involved in various processes, including motor, associative, cognitive,and mnemonic functions. A major role of the basal ganglia is tointegrate sensorimotor, associative, and limbic information toproduce context-dependent behaviors (Nauta and Domesick, 1984;Graybiel, 1995), a function that is evident from behavioral andphysiological analyses (Wurtz and Hikosaka, 1986; Schultz et al.,1993; Graybiel et al., 1994; Aosaki et al., 1995). The basal gangliareceive topographical projections from all functional territoriesof the cortex that are directed to the neostriatum and its ventralhomolog the nucleus accumbens (Kunzle, 1975; Goldman and Nauta,1977; Van Hoesen et al., 1981; Nauta and Domesick, 1984; Selemonand Goldman-Rakic, 1985; Alexander et al., 1986, 1990; McGeorgeand Faull, 1989; Flaherty and Graybiel, 1991; Hoover and Strick,1993; Groenewegen and Berendse, 1994; Joel and Weiner, 1994).Although the results of anatomical analyses suggest that the segregationof functional information imparted by the topographical corticalinput is maintained at each level of a series of segregated, parallelbasal ganglia-thalamocortical loops (Alexander et al., 1986, 1990;Hoover and Strick, 1993; Groenewegen and Berendse, 1994; Joeland Weiner, 1994; Lynch et al., 1994), it is clear that systemsmust exist within these loops where integration of the diverseinformation occurs at the synaptic level. Several sites or systemshave been proposed to subserve this function, including the localcircuit neurons of the neostriatum and nucleus accumbens (Gerfen,1984; Chesselet and Graybiel, 1986; Kubota and Kawaguchi, 1993;Bolam and Bennett, 1995), the ascending projections of midbraindopamine neurons (Somogyi et al., 1981; Nauta and Domesick, 1984;Gerfen et al., 1987; Jimenez-Castellanos and Graybiel, 1987; Smithand Bolam, 1990), the pattern of striatal innervation of neuronsof the globus pallidus and substantia nigra (Francois et al.,1984; Percheron et al., 1984, 1987; Yelnik et al., 1984), theinnervation of the pedunculopontine region by the internal segmentof the globus pallidus (Smith and Shink, 1995), and "open" cortico-basalganglia-thalamocortical loops (Joel and Weiner, 1994). We haverecently demonstrated an additional system that is part of theindirect pathway of information flow through the basal ganglia,which may underlie a powerful mechanism for the integration ofdiverse information in the basal ganglia (Bevan et al., 1995b,1996). By double anterograde tracing we demonstrated that neuronsof functionally diverse regions of the pallidal complex, i.e.,globus pallidus (motor and associative) and the ventral pallidum(limbic), made convergent synaptic contacts both with neuronsof the substantia nigra pars reticulata (basal ganglia outputneurons) and with the dopamine neurons of the ventral midbrain,in addition to providing segregated inputs to the substantia nigra.The innervation by both types of pallidal neurons took the formthat is typical of pallidal innervation described previously (Smithand Bolam, 1989, 1991; Bolam et al., 1993), i.e., both sets ofterminals formed basket-like, multiple, GABA-positive symmetricalsynaptic contacts with the cell body and proximal dendrites oftheir targets.

Neurons of the pallidal complex, as part of the indirect pathway of information flow through the basal ganglia (Albin et al.,1989; Alexander and Crutcher, 1990; DeLong, 1990), in additionto projecting to the substantia nigra also project to the otheroutput nucleus of the basal ganglia, i.e., the entopeduncularnucleus (Kincaid et al., 1991; Bolam and Smith, 1992) and thesubthalamic nucleus (DeLong, 1990). The question we address inthis report is whether the same rules of synaptic innervationof neurons in the substantia nigra by neurons of the pallidalcomplex also apply to the innervation of neurons in the entopeduncularnucleus and subthalamic nucleus. In particular, we have lookedfor evidence of convergence of synaptic input from functionallydistinct regions of the pallidal complex onto the same individualneurons in each of these two target nuclei.

Some of the data reported in this manuscript have been published previously in abstract form (Bevan and Bolam, 1995a; Bevanet al., 1995b; Clarke et al., 1996a).

MATERIALS AND METHODS
Preparation of tissue. All surgical procedures were carried out on male Sprague Dawley rats (250-350 gm) under deep anesthesia,which was induced and maintained by injection of pentobarbitone(Sagatal, 60 mg/kg, i.p.). Injections of neuronal tracers wereplaced into different regions of the pallidal complex under stereotaxicguidance, using coordinates derived from the atlas of Paxinosand Watson (1986). The rats were maintained on a 12 hr light/darkcycle, with free access to food and water. Environmental conditionsfor housing of the rats and all procedures that were performedon them were in accordance with the Animals (Scientific Procedures)Act 1986 and with the policy on the use of animals in neuroscienceresearch issued by the Society for Neuroscience.

Double anterograde tracing combined with pre- and post-embedding immunocytochemistry at the light and electron microscopiclevels was performed in eight rats as described previously (Smithand Bolam, 1991), except that biotinylated dextran amine (BDA)was used as one of the tracers (Veenman et al., 1992). While underdeep anesthesia, the rats received iontophoretic injections (5-9µA, 7 sec on/7 sec off, 20 min) of Phaseolus vulgaris-leucoagglutinin[PHA-L; 2.5% in 0.01 M phosphate buffer (PB), pH 8.0; Vector Laboratories,Peterborough, UK] (Gerfen and Sawchenko, 1984) in the ventralpallidum and biotinylated dextran amine (10% in 0.9% sodium chloride;Molecular Probes, Eugene, OR) in the globus pallidus. In one casethe injections were reversed.

After a survival period of 1 week, the animals were reanesthetized, perfused with 100 ml PBS (0.01 M phosphate, pH 7.4) for1-2 min, and then perfused with 300 ml of 0.1-0.5% glutaraldehydeand 2-3% paraformaldehyde in PB (0.1 M, pH 7.4) for 20 min, followedby 100-200 ml of 2-3% paraformaldehyde for 10 min. After fixationthe brain was removed from the cranium, divided into 5-mm-thickcoronal slices, and stored in PBS at 4°C before further processing.From each slice, 60 µm coronal sections through the injectionsites, the striatal complex, the subthalamic nucleus, and theentopeduncular nucleus were taken by a vibrating microtome andcollected in PBS. Sections for electron microscopy were freeze-thawedas described previously (von Krosigk and Smith, 1991) and thenwashed several times in PBS before further processing. Sectionsfor light microscopy alone had 0.3% Triton X-100 included in thediluent for the antibodies and peroxidase complex.

Visualization of neuronal tracers. A series of sections were processed for the light microscopic visualization of both tracers.The BDA was visualized by incubation of the sections in an avidin-biotin-peroxidasecomplex (1:100 dilution; Vector Laboratories) in PBS containing1% bovine serum albumin at room temperature for 4 hr or overnightat 4°C. Peroxidase linked to BDA by the avidin-biotin bridge wasrevealed by placing the sections in Tris buffer (0.05 M, pH 7.6)containing 0.025% 3,3 $'$ -diaminobenzidine tetrahydrochloride (DAB)and 0.006% hydrogen peroxide for 10-15 min. The reaction was terminatedby rinsing the sections several times in Tris buffer.

The PHA-L was then visualized by incubating the sections in rabbit anti-PHA-L antibody (1:1000 dilution; Dako, High Wycombe,UK) overnight at room temperature or for 48 hr at 4°C. After manywashes in PBS, the sections were incubated in a solution of goatanti-rabbit IgG (1:100; Dako) at room temperature for 2 hr followedby a 2 hr incubation in rabbit peroxidase anti-peroxidase complex(1:100; Dako). Bound peroxidase was revealed by incubation inhydrogen peroxide (0.00075%), using DAB (0.015%) in the presenceof nickel ammonium sulfate (0.5%) as the chromogen. The antiserawere diluted in PBS containing 1% bovine serum albumin and 2%normal goat serum.

Alternate sections through the injection sites were processed to reveal substance P [1:50 rat anti-substance P (Cuello etal., 1979); 1:100 goat anti-rat, Dako; 1:100 rat PAP, Incstar)immunoreactivity, using DAB as the chromogen for the peroxidasereaction (see above). Substance P is a marker of the ventral pallidumand was used to determine the precise location of the injectionsites (Haber and Nauta, 1983; Groenewegen et al., 1993).

The majority of the sections was processed for correlated light and electron microscopic analysis. All antibody incubationsand peroxidase reactions were carried out as described above,except that Triton X-100 was not included in the diluent and benzidinedihydrochloride (BDHC) was used as the chromogen to visualizePHA-L-labeled structures (Smith and Bolam, 1991, 1992; Bevan etal., 1994a). The strict safety precautions described by Yung etal. (1996) were used when the BDHC as well as the DAB were handled.

Processing of sections for correlated light and electron microscopy. After visualization of the tracers, the sections containinganterogradely transported tracers were placed flat at the bottomof a Petri dish and post-fixed in 1% osmium tetroxide (Oxchem,UK) (in 0.01 M PB at pH 6.8) for 20-30 min. The sections werethen washed in PB and rapidly dehydrated through a graded seriesof dilutions of ethanol. To enhance the contrast of the tissuein the electron microscope, the sections were stained with 1%uranyl acetate (Taab) at the 70% ethanol phase. The sections werewashed twice for 10 min in propylene oxide and placed in resin(Durcupan; Fluka, Buchs, Switzerland) overnight. Finally, thesections were embedded in resin on microscope slides, placed inan oven, and cured for 48 hr at 60°C.

Analysis of material. The sections that included the injection sites were examined in the light microscope, and the locationand extent of the tracer injections in the pallidal complex wereassessed and compared with the distribution of substance P immunoreactivityin the adjacent sections. The anterograde labeling arising fromthe tracer deposits was plotted with the aid of a drawing tube.Particular note was made of neurons that were apposed by anterogradelylabeled boutons derived from both tracer deposits. Sections preparedfor correlated light and electron microscopy were examined inthe light microscope, and individual neurons that were apposedby both sets of anterogradely labeled terminals in the entopeduncularnucleus, lateral hypothalamus, or subthalamic nucleus, or regionsthat contained a large number of both types of terminals werephotographed, cut out from the slides, and glued to blank resinblocks. Serial ultrathin sections were cut on a Reichert-JungUltracut-E ultramicrotome and collected on Pioloform-coated copperor gold single-slot grids. The ultrathin sections were contrastedwith lead citrate for 1-2 min and examined in a Phillips CM10or 410 electron microscope.

Synaptology of neurons of the subthalamic nucleus. To characterize the afferent synaptology of neurons of the subthalamicnucleus, seven rats received iontophoretic deposits (5-10 µA,7 sec on/7 sec off, 15 min) of the tracer neurobiotin (5% in 0.9%NaCl; Vector Laboratories) (Kita and Armstrong, 1991; Lapper andBolam, 1991) in the substantia nigra. After a survival time of1 day, the animals were perfused and sectioned as described above.Sections of the subthalamic nucleus were incubated to reveal theinjected and transported tracer, and the tissue was prepared forcorrelated light and electron microscopy essentially as describedfor BDA. Individual neurons in the subthalamic nucleus that werelabeled extensively with the neurobiotin were identified, drawn,photographed, and re-embedded for electron microscopic analysis.Serial sections were collected and examined in the electron microscope.The position of each terminal forming synaptic contact with thesubthalamic neurons was noted. The terminals were classified accordingto their morphology and the nature of the postsynaptic specialization.The presence of GABA in the synaptic boutons was then tested bypost-embedding immunocytochemistry (see below). Cross-sectionalareas of labeled terminals were determined from photographs, usinga digitizing pad and MacStereology software.

Post-embedding immunocytochemistry for GABA. To test for the presence of fixed GABA in anterogradely labeled and nonlabeledterminals in the entopeduncular nucleus, lateral hypothalamus,and subthalamic nucleus, ultrathin sections were collected ongold grids and labeled by the post-embedding immunogold method.The method was a slight modification of that described by Phendand colleagues (1992). The grids were first washed in 0.05 M Trisbuffer, pH 7.6, containing 0.9% NaCl and 0.01% Triton X-100 (TBS-Triton)and then incubated overnight at room temperature on drops of a1:5000-15,000 dilution of a rabbit anti-GABA antiserum (code 9;Hodgson et al., 1985; Somogyi and Hodgson, 1985; Somogyi et al.,1985) in TBS-Triton. After several washes in TBS-Triton and onewash in TBS at pH 8.2, the grids were incubated for 1-1.5 hr atroom temperature in a 1:25 dilution of 15 nm gold-conjugated goatanti-rabbit IgG (BioCell, Cardiff, UK) in TBS at pH 8.2. The gridswere washed in TBS at pH 8.2 and then in water and stained with1% aqueous uranyl acetate for 1-1.5 hr and then with lead citrate.The sections were then examined in the electron microscope.

Immunoreactivity for GABA was detected by the presence of the electron-dense immunogold particles overlying labeled structures.To quantify the immunoreactivity, the density (particles/µm²) of immunogold particles overlying individual structures wascalculated. The density of labeling overlying terminals was correctedfor nonspecific binding of the antibody to tissue-free resin bysubtracting the density of gold particles overlying the lumenof capillaries in the same ultrathin section. The index of GABAimmunoreactivity for each bouton was then calculated by normalizingthe corrected density with respect to the labeling associatedwith GABA-immunonegative terminals forming asymmetrical synapseson the same ultrathin section.

RESULTS

Light microscopic analysis
Location of injection sites The PHA-L was revealed as a blue reaction product produced by the nickel/DAB, and the BDA as a brown reaction product producedby the DAB. The sites of injection of PHA-L into the ventral pallidumor BDA into the globus pallidus (or the reverse in a single case)were characterized by densely labeled neurons surrounded by ahalo of diffuse extracellular staining (Fig. 1A,B). A total ofeight cases that had injections located discretely in both divisionsof the pallidal complex were used in this analysis. Some of theseanimals have also been used in an analysis of the pallidal innervationof the substantia nigra (Bevan et al., 1996). In each case thedeposits of tracers in the ventral pallidum were confined to thesubcommissural region of the pallidal complex and included boththe lateral and medial subdivisions (Figs. 1B, 2; also see illustrationsin Bevan et al., 1996). The localization of the deposits withinthe ventral pallidum was confirmed by substance P immunostainingof sections adjacent to those incubated to reveal the tracer (Fig.1C). Rarely, small numbers of labeled neurons were observed inthe transitional zone where the boundary between the globus pallidusand ventral pallidum is difficult to define. The deposits of tracersin the globus pallidus were confined to that nucleus and did notencroach on the ventral pallidum or the medially placed internalcapsule (Figs. 1A, 2). In two cases, small numbers of neuronswere labeled in the neostriatum along the injection tract. Inmost of the cases the deposits were confined to the central regionof the GP in its rostral two thirds.
Fig. 1. Light micrographs of anterograde labeling from the ventral pallidum and globus pallidus (GP) in the entopeduncular nucleus(EP) and subthalamic nucleus (STN). A-C, Sites of deposit of BDAin the globus pallidus (A) were revealed by using DAB as the chromogen,and PHA-L in the ventral pallidum (B) were revealed by using nickel-DABas the chromogen for the peroxidase reaction. The extent of thetracer deposit in the ventral pallidum (arrowheads) was assessedby staining of adjacent sections to reveal substance P immunoreactivity(arrowheads) (C). D, Medium-power micrograph of anterograde labelingin the subthalamic nucleus. The fibers anterogradely labeled fromthe ventral pallidum (blue) occupy the medial and dorsal aspectsof the STN, whereas those from the globus pallidus (brown) occupythe more lateral parts; however, the two sets of anterogradelylabeled fibers are mixed at the interface between the projections.Note that the width of the fields of anterograde labeling is wellwithin the dendritic diameter of subthalamic neurons. E, Medium-powermicrograph of anterograde labeling in the entopeduncular nucleus.The fibers derived from the globus pallidus (brown; some indicatedby arrows) and those derived from the ventral pallidum (blue;some indicated by arrowheads) are largely separate at this level,although there are areas of overlap of the two sets of fibers(some indicated by open arrows and shown at higher magnificationin H). F, G, High-power micrographs of unstained neuronal perikaryain the STN that are closely apposed by axonal swellings derivedfrom both the ventral pallidum (blue; some indicated by arrowheads)and the globus pallidus (brown; some indicated by arrows). Individualperikarya are apposed by several boutons from each site. H, High-powermicrograph of the region of the entopeduncular nucleus indicatedby open arrows in E. An unstained neuronal perikaryon (n) anddendrite (d) are closely apposed by axonal swellings derived fromboth the ventral pallidum (blue; some indicated by arrowheads)and the globus pallidus (brown; some indicated by arrows). ac,Anterior commissure; cp, cerebral peduncle; ic, internal capsule.Scale bars: A-C (shown in A), 500 µm; D, E, (shown in D), 100µm; F-H (shown in H), 20 µm.
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Fig. 2. Schematic representations of the sites of deposit of PHA-L in the ventral pallidum (VP) and BDA in the globus pallidus (GP)and the site of anterograde transport in the entopeduncular nucleus(EP) and subthalamic nucleus (STN) in three animals (A-C). Dotsat the injection sites represent individual neurons that havetaken up the PHA-L (blue) or the BDA (red). The blue and red stipplingof the two rostrocaudal levels of the EP and STN represent theanterogradely labeled fibers from the VP and GP, respectively.Although the topography of the two projections is distinct, manyneurons were identified (green dots) that were apposed by boutonsderived from both the VP and GP. ac, Anterior commissure; cp,cerebral peduncle; ic, internal capsule.
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The deposits of either BDA or PHA-L in ventral pallidum or globus pallidus gave rise to retrograde labeling of neurons inthe striatal complex in addition to anterograde labeling (seebelow). The deposits of tracer in the ventral pallidum gave riseto retrogradely labeled neurons in the nucleus accumbens and mostventral parts of the neostriatum, whereas the deposits of tracerin the globus pallidus gave rise to retrograde labeling in thedorsal parts of the neostriatum (Fig. 3).
Fig. 3. Retrograde labeling in the striatal complex after tracer deposits in the ventral pallidum and the globus pallidus. Low-powermicrograph of the neostriatum and nucleus accumbens of the sameanimal as illustrated in Figure 2C. The section was incubatedto reveal retrogradely transported PHA-L that was injected inthe ventral pallidum and BDA that was injected in the globus pallidus.Although it is difficult to distinguish the labeling in this blackand white micrograph, neurons retrogradely labeled from the globuspallidus (labeled with DAB; area indicated by arrowheads) arepresent only in the dorsal part of the neostriatum, whereas neuronsretrogradely labeled from the ventral pallidum (labeled with Ni-DAB;area indicated by arrowheads) are present only in the most ventralaspects of the neostriatum and the nucleus accumbens. ac, Anteriorcommissure; lv, lateral ventricle; nac, nucleus accumbens; ns,neostriatum. Scale bar, 0.5 mm .
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Anterograde labeling Each of the deposits of tracer in the ventral pallidum or the globus pallidus gave rise to anterograde labeling in the neostriatum,nucleus accumbens, entopeduncular nucleus, lateral hypothalamus,subthalamic nucleus, substantia nigra/ventral tegmental area,and thalamus. The anterograde labeling in the ventral mesencephalonis the subject of separate communications (Bevan et al., 1996)and will thus not be dealt with further. The anterograde labelingfollowed a topographical ordering that was consistent with previousobservations (Smith and Bolam, 1989, 1991; Groenewegen et al.,1993). Tracer deposits in the globus pallidus led to anterogradelabeling that was largely confined to the more dorsal and lateralparts of the entopeduncular nucleus, whereas the tracer depositsin the ventral pallidum led to anterograde labeling in the moremedial and ventral parts of the entopeduncular nucleus that extendedinto the lateral hypothalamus (Fig. 2). Similarly, in the subthalamicnucleus, anterograde labeling derived from the globus palliduswas located more laterally than were anterogradely labeled fibersderived from the ventral pallidum (Figs. 1E, 2). The tracer depositsin the ventral pallidum gave rise to labeling in the medial anddorsal subthalamic nucleus and also extended medially into thelateral hypothalamus (Figs. 1D, 2).

Despite the topographic separation of the majority of anterogradely labeled structures derived from the ventral pallidum andthe globus pallidus, zones of overlap were observed in the entopeduncularnucleus/lateral hypothalamus and the medial and dorsal subthalamicnucleus (Figs. 1D,E, 2).

At high magnification the morphology and organization of the anterogradely labeled fibers and boutons were consistent withprevious observations (Haber et al., 1985; Smith et al., 1990;Bolam and Smith, 1992; Groenewegen et al., 1993). Thus the labeledstructures derived from either the globus pallidus or the ventralpallidum gave rise to a dense meshwork of fibers (Fig. 1D,E) thatpossessed large boutons (Fig. 1F-H). The boutons often gave riseto a basket-like innervation of unstained neuronal perikarya (Fig.1F-H). In regions of overlap between the two sets of anterogradelylabeled structures, fibers and axonal swellings were closely intermixed.Boutons derived from both the ventral pallidum and the globuspallidus were often apposed to the same unstained neuron (Fig.1F-H).

Electron microscopic analysis
Because it is not possible to distinguish DAB and nickel/DAB reaction products at the electron microscopic level, the electronmicroscopic analysis was conducted on material in which the anterogradelytransported PHA-L was revealed by using BDHC as the chromogenfor the peroxidase reaction, and the BDA was revealed by usingDAB as the chromogen. The two reaction products are readily distinguishableat the electron microscopic level (Levey et al., 1986; Smith andBolam, 1991; Bevan et al., 1994a,b). The DAB reaction productpresumably forms as a precipitate during the peroxidase reaction;it is thus floccular and adheres to the external surface of organellemembranes, including vesicles and mitochondria and the internalsurface of the plasma membrane (Figs. 4A,C, 5B, 6F, 7B, 8C). Itis distributed characteristically throughout the labeled structure.In lightly labeled structures, it appears as an electron-densematerial lining membranes (Figs. 5B, 7B), but in more heavilylabeled structures it appears as an amorphous material that fillsthe whole of the structure, often obscuring the internal details(Figs. 4A, 6F, 8C). The BDHC reaction product, in contrast, appearsto be crystalline, having an irregular, nonfloccular appearance(Figs. 4A,B, 5C, 6C-E, 7C,D, 8B). As such, the reaction productdoes not adhere to membranes and is commonly found in only partof the labeled structure, leaving regions free of reaction product(Figs. 4A,B, 5C, 6C-E, 8B). The BDHC reaction product is oftenmore electron-dense than the DAB reaction product (Fig. 4).
Fig. 4. Synaptic convergence of terminals derived from different functional domains of the pallidal complex in the entopeduncularnucleus. A, Electron micrograph of part of a proximal dendriteof a neuron in the entopeduncular nucleus (EPn). The neuron isapposed by three anterogradely labeled boutons, each of whichforms symmetrical synaptic contact with the neuron (arrows). Twoof the boutons contain the BDHC peroxidase reaction product thatwas used to localize the PHA-L anterogradely transported fromthe ventral pallidum (b_VP). The third bouton (b_GP) contains theDAB reaction product that was used to localize the BDA anterogradelytransported from the globus pallidus. Note that the BDHC reactionproduct that labels the terminals from the ventral pallidum hasan irregular appearance and occupies only part of the labeledbouton, leaving many vesicles visible that do not have reactionproduct associated with them. In contrast, the DAB reaction productthat labels the boutons from the globus pallidus is amorphousand occupies the whole of the labeled structure. B, A serial sectionof the upper of the two boutons derived from the ventral pallidum.This section was processed by the post-embedding immunogold methodto reveal GABA immunoreactivity. The bouton has a high densityof immunogold particles associated with it (index of GABA immunoreactivity= 3.79). C, Serial section of the bouton derived from the globuspallidus labeled by the post-embedding immunogold method to revealGABA immunoreactivity. The bouton has a high density of immunogoldparticles associated with it (index of GABA immunoreactivity =7.51). Scale bar (shown in A): A-C, 1 µm.
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Fig. 5. Synaptic convergence of terminals derived from different functional domains of the pallidal complex in the entopeduncularnucleus. A, The large proximal dendrite of a neuron in the entopeduncularnucleus (EPn) is apposed by two anterogradely labeled boutons.The bouton, shown at high power in B, contains the floccular DABreaction product that adheres to the external surface of vesicleand mitochondrial membranes and indicates that it is derived fromthe globus pallidus (b_GP). The bouton forms symmetrical synapticcontact (arrow) with dendrite. The other bouton contains the BDHCreaction product that is granular in appearance and is locatedonly at restricted sites in the bouton (granules indicated bycurved arrows in C), indicating that it is derived from the ventralpallidum (b_VP). It forms multiple symmetrical contacts with thedendrite (arrows). Scale bars: A, 5 µm; B, 1 µm.
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Fig. 6. Synaptic convergence of terminals derived from different functional domains of the pallidal complex in the lateral hypothalamusadjacent to the entopeduncular nucleus. A, B, Low-power micrographsat two levels of a neuron in the lateral hypothalamus (LHn) thatwas apposed by four anterogradely labeled terminals. Three ofthe terminals (b_VP), the positions of which are indicated by arrowsand the letters C, D, and E, are shown at higher magnificationin C, D, and E, respectively. Each contains the BDHC reactionproduct (some granules of which are indicated by curved arrows)that was used to reveal the PHA-L transported from the ventralpallidum. The reaction product characteristically occupies onlypart of the labeled boutons. In each case the boutons form symmetricalsynaptic contact (arrows) with the perikaryon (C, D) or the dendrite(d in E). The micrograph E is a serial section of that in B; themyelinated axon (ma) is indicated by an arrowhead in B. The fourthbouton (b_GP), the position of which is indicated by F in B, isshown at high magnification in F and contains the floccular DABreaction product that adheres to membranes and occupies the wholeof the labeled structure, identifying it as arising from the globuspallidus. This bouton also makes symmetrical synaptic contact(arrow) with the perikaryon of the lateral hypothalamic neuron.Glial cells (g) and a capillary (c) are labeled for correlationbetween the two low-power micrographs. Scale bars: A, B (shownin B), 10 µm; C-E (shown in E), 1 µm.
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Fig. 7. Synaptic convergence of terminals derived from different functional domains of the pallidal complex in the subthalamic nucleus.A, Part of the cell body of a neuron in the subthalamic nucleus(STNn) that is apposed by three anterogradely labeled terminals(b_VP, b_GP) shown at higher magnification in B-D. In this animalthe injections were reversed, i.e., the PHA-L was injected inand anterogradely transported from the globus pallidus, and theBDA was injected in and anterogradely transported from the ventralpallidum. One of the boutons is lightly labeled with the DAB reactionproduct that adheres to vesicle and mitochondrial membranes, identifyingit as arising in the ventral pallidum (b_VP). It is shown at highermagnification in B. The bouton forms symmetrical synaptic contacts(arrows) with the subthalamic neuron. The other two boutons, shownat high magnification in C and D, are strongly labeled with thecrystalline BDHC reaction product, which has an irregular appearance.These boutons are thus derived from the globus pallidus (b_GP)and form symmetrical synaptic contacts with the neuron (arrows).Note that micrograph D is a different serial section of that shownin A. Scale bars: A, 2 µm; B-D (shown in C), 1 µm.
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Fig. 8. Synaptic convergence of terminals derived from different functional domains of the pallidal complex in the subthalamic nucleus.A, Cell body of a neuron in the subthalamic nucleus (STNn) thatis postsynaptic to two anterogradely labeled boutons. The boutonb_VP, shown at high magnification in B, contains the crystallineBDHC reaction product that occupies only part of the bouton. TheBDHC was used to reveal the PHA-L transported from the ventralpallidum. The bouton forms symmetrical synaptic contact (arrow)with the neuron. The bouton b_GP, shown at higher magnificationin C, is intensely labeled with the floccular DAB reaction productused to localize the BDA transported from the globus pallidus.The reaction product fills the whole of the bouton and obscuresmost internal structures. This bouton forms symmetrical synapticcontact with the neuron (arrow). Scale bars: A, 3 µm; B, C (shownin C), 1 µm.
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Terminals derived from the globus pallidus Consistent with previous observations (Smith et al., 1990; Bolam and Smith, 1992), the terminals derived from the globus pallidusin both the entopeduncular nucleus and the subthalamic nucleuswere large and usually contained several mitochondria and pleomorphicvesicles often clustered at the active zone (Figs. 4, 5B, 6F,7C,D, 8C). The boutons form symmetrical synapses with fairly shortactive zones, but a single bouton may form more than one activezone with the same postsynaptic structure (Fig. 7C). The postsynaptictargets of the boutons derived from the globus pallidus includedperikarya and large and small diameter dendrites in both the entopeduncularnucleus and the subthalamic nucleus. In general terms, the distributionsof postsynaptic targets are consistent with previous observations(Table 1).

Table 1. Postsynaptic targets of pallidal terminals

Source Target region Postsynaptic target (% distribution)

Perikarya Large dendrites Small dendrites

Ventral pallidum EP/LH (71) 31 19.7 49.3

Globus pallidus^a EP (162) 12.8 23.3 64

Ventral pallidum STN/LH (90) 21 18.9 60

Globus pallidus^b STN (187) 31 39 30

Globus pallidus^c SNr (105) 54 32 14

Postsynaptic targets of terminals derived from the ventral pallidum in the entopeduncular/lateral hypothalamus (EP/LH) andthe subthalamic nucleus/lateral hypothalamus (STN/LH) obtainedin this study compared with data on terminals from the globuspallidus obtained in other studies. Large dendrites and smalldendrites refer to those dendrites with a diameter greater orsmaller than 1.5 µm in diameter in the EP/LH and substantia nigrareticulata (SNr) and 1 µm in the STN/LH. Figures represent thepercentage of the number of terminals shown in brackets in contactwith different elements.

Data obtained from ^aBolam and Smith, 1992; ^bSmith et al., 1990; ^cSmith and Bolam, 1991.

Terminals derived from the ventral pallidum Terminals anterogradely labeled from the ventral pallidum displayed similar morphological features whether they were observedin the entopeduncular nucleus, lateral hypothalamus, or subthalamicnucleus. The features were similar to those of terminals derivedfrom the dorsal aspect of the pallidal complex, the globus pallidus(see above and Smith et al., 1990; Smith and Bolam, 1991; Bolamand Smith, 1992). They were large boutons with a mean (±SE) cross-sectionalarea in the entopeduncular nucleus/lateral hypothalamic regionof 0.75 ± 0.04 µm² (n = 71; range, 0.27-1.5 µm²) and in the subthalamic nucleus/lateral hypothalamic region of0.63 ± 0.03 µm² (n = 88; range, 0.17-1.8 µm²). They usually contained several mitochondria and clusters ofpleomorphic vesicles, and they formed symmetrical synaptic contactwith perikarya and both proximal and distal dendrites of neuronsin each of the areas examined (Table 1). They often formed multiplecontacts with their targets (Fig. 5C). As has been observed previouslyfor terminals derived from the globus pallidus (Bolam and Smith,1992; Bolam et al., 1993), a high proportion of terminals derivedfrom the ventral pallidum made synaptic contact with perikarya,although most were in contact with dendrites with diameters of<1.5 µm (Table 1). Post-embedding immunolabeling revealed thatthe terminals derived from the ventral pallidum in the entopeduncularnucleus, the lateral hypothalamus, and the subthalamic nucleus,like those derived from the globus pallidus (Smith et al., 1990;Smith and Bolam, 1991; Bolam and Smith, 1992), were significantly(p < 0.0005, Mann-Whitney U test) enriched in GABA immunoreactivitywhen compared with terminals forming asymmetrical synapses inthe same section (index of GABA immunoreactivity in the entopeduncularnucleus/lateral hypothalamus: 4.71 ± 0.41, n = 22; in the subthalamicnucleus/lateral hypothalamus: 16.97 ± 1.74, n = 30).
Synaptic convergence of terminals derived from the ventral pallidum and the globus pallidus The sections prepared for electron microscopic analysis, i.e., those in which BDHC and DAB were used as chromogens for theperoxidase reactions, were examined for areas of close overlapbetween the two sets of anterogradely labeled terminals and forindividual neuronal perikarya and large proximal dendrites thatwere apposed by boutons derived from both the ventral pallidumand the globus pallidus. These regions were re-embedded on blocksof resin and resectioned for electron microscopy. Using this correlatedlight and electron microscopic approach, we examined six neuronsfrom the entopeduncular nucleus (from two rats), two neurons fromthe lateral hypothalamus adjacent to the entopeduncular nucleus(from two rats), and six neurons from the subthalamic nucleus(from three rats).

In the entopeduncular nucleus, synaptic convergence of terminals derived from the ventral pallidum and those derived fromthe globus pallidus was observed at the level of the perikaryaand proximal dendrites (Figs. 4, 5). In most cases, more thanone labeled terminal from either the ventral pallidum or the globuspallidus was involved in the convergence (Fig. 4). In each ofthe cases, the structures postsynaptic to the anterogradely labeledterminals also received afferent synaptic input from unlabeledterminals that had the morphology of pallidal terminals, of terminalsderived from the striatum (Bolam and Smith, 1992), from the subthalamicnucleus (Bevan et al., 1994b), and from the mesopontine tegmentum(Clarke et al., 1996b) (not illustrated). Of the six entopeduncularneurons re-embedded for electron microscopic analysis, all wereconfirmed as receiving convergent synaptic input from both theventral pallidum and the dorsal globus pallidus.

In the lateral hypothalamus, synaptic convergence of both sets of anterogradely labeled terminals was observed at the levelof the perikarya and proximal dendrites in the two neurons thatwere examined by correlated light and electron microscopy. Bothneurons were observed to receive multiple inputs from labeledterminals (Fig. 6).

In the subthalamic nucleus, terminals derived from the ventral pallidum and terminals derived from the globus pallidus madeconvergent synaptic contact with the same postsynaptic structure(Figs. 7, 8). Of the six neurons re-embedded for electron microscopicanalysis, two were identified as receiving convergent input atthe level of the perikaryon. In the four other cases, either thesynaptic specializations were not observed or the terminals madesynaptic contact with different structures. An additional perikaryonand distal dendrite, which were not identified at the light microscopiclevel before the electron microscopic analysis, were observedto receive convergent synaptic input from the ventral pallidumand the globus pallidus. The neuronal profiles receiving the convergentsynaptic inputs were also postsynaptic to unlabeled terminalsthat had the morphological features of pallidal terminals andterminals forming asymmetrical synapses that were probably derivedfrom the cortex, the thalamus, and the mesopontine tegmentum (Bevanand Bolam, 1995b; Bevan et al., 1995a).
Afferent synaptic input to neurons of the subthalamic nucleus The double anterograde labeling allowed only the analysis of pallidal inputs to the perikarya and proximal regions of neuronsin the subthalamic nucleus, entopeduncular nucleus, and lateralhypothalamus.Because it is known that the dendrites of neurons of the subthalamicnucleus are oriented so that they cross functional territoriesdefined by the pallidal input, the distal dendrites of subthalamicneurons were examined for synaptic input from pallidal terminalsdefined on morphological and neurochemical grounds. Five neuronsin the subthalamic nucleus (from two of the injected animals)that were retrogradely labeled from the substantia nigra wereexamined in serial sections in the electron microscope. The neuronswere selected on the basis of the extent of their dendritic labelingand the orientation and position of the dendrites in relationto the functional territories of the subthalamic nucleus. Thedendrites beyond 100 µm from the perikaryon were examined in theelectron microscope. Pallidal terminals, defined on the basisof morphology of the bouton, the type of synaptic specialization,and the presence of relatively high levels of GABA immunoreactivity(mean ± SEM of the index of GABA immunoreactivity, 8.96 ± 0.72;n = 37), were found in synaptic contact with all parts of thedendritic trees examined, including distal dendrites as far as330 µm from the perikaryon (Fig. 9, Table 2).
Fig. 9. Topology of pallidal terminals in synaptic contact with the distal dendrites of neurons in the subthalamic nucleus. A, Drawingof a neuron in the subthalamic nucleus (inset shows the positionin the STN) that was labeled by the retrograde transport of neurobiotinfrom the substantia nigra. This neuron was chosen for analysisbecause of the extent of the dendritic labeling that crosses functionalterritories as defined by pallidal inputs. The arrowheads indicatethe position at which synaptic input from pallidal terminals definedon the basis of morphology and neurochemistry were identified.Three additional pallidal inputs indicated by the location ofthe letters C, D, and E are shown at the electron microscopiclevel in C, D, and E, respectively. A $'$ , B, and C show the correlationbetween the light and electron microscopic levels. The distalpart of the dendrite is indicated by the arrowheads in the lightmicrograph (A) and in the electron micrograph (B). Three otherneurobiotin-labeled structures (arrows) and a capillary (c) areindicated on both micrographs for the purpose of correlation.C, A bouton (b; also indicated in micrograph B) has the morphologicalfeatures of a terminal derived from the pallidal complex, formssymmetrical synaptic contact with the dendrite (d) ~245 µm fromthe perikaryon, and has a high level of GABA immunoreactivityassociated with it (index of GABA immunoreactivity is 5.8 comparedwith GABA-negative terminals forming asymmetrical synapses inthe same section). The bouton (b) in D also possesses the featuresof a pallidal terminal, is ~145 µm from the perikaryon, and hasan index of GABA immunoreactivity of 11.2. In E the bouton (b)forms symmetrical synaptic contact with the dendrite (arrow) ~100µm from the perikaryon and has an index of GABA immunoreactivityof 6.54. The asterisk in D indicates a bouton that forms symmetricalsynaptic contact with a dendrite and has an index of GABA immunoreactivityof 9.49. The asterisk in E indicates a terminal that forms anasymmetrical synapse with a spine and is GABA-negative (indexof GABA immunoreactivity 1.19). Scale bars: A, 20 µm; A $'$ , 20 µm;B, 5 µm; C-E (shown in C), 0.5 µm.
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Table 2. The location and numbers of pallidal boutons in synaptic contact with dendrites of neurons in the subthalamic nucleus

Neuron number Location and numbers of synaptic boutons (µm from cell body)

100-150 150-200 200-250 250-300 300+

1 4

2 3 4

3 0 2 3

4 0 0 7 5 1

5 4 1 4 3

Total 11 7 14 8 1

For each neuron, a single dendrite was serially sectioned, and the number of pallidal terminals was identified on the basisof morphological features, type of synaptic specialization, andin most cases (35/41), the presence of GABA immunoreactivity.The analysis was commenced at 100 µm from the perikaryon and continuedas far as the dendritic staining extended or until it left thesection. For each neuron the last figure represents the maximumextent.

DISCUSSION
The findings of the present study together with data from a previous study (Bevan et al., 1996) enable us to define anatomicalsubstrates by which information carried by the descending projectionsof the pallidal complex may be synaptically integrated at thelevel of the output neurons of the basal ganglia in the substantianigra pars reticulata and the entopeduncular nucleus, and at thelevel of neurons in the lateral hypothalamus and subthalamic nucleus(Fig. 10). First, our findings in the present paper confirm previousobservations that functionally distinct regions of the pallidalcomplex provide a dense, topographic innervation of the entopeduncularnucleus and the subthalamic nucleus and their medial extensionsin the lateral hypothalamus (see references cited in introductoryremarks). Second, the double anterograde tracing revealed thatat the interface between topographically adjacent projections,there is a zone of overlap in which individual neurons are apposedby terminals derived from both the globus pallidus and the ventralpallidum. Third, neurons in the zones of overlap receive convergentsynaptic input at the level of the cell body and proximal dendritesfrom the functionally distinct, GABAergic, pallidal projections.Fourth, as has been reported for terminals from the globus pallidus,the postsynaptic targets of terminals derived from the ventralpallidum include distal dendrites as well as perikarya and proximaldendrites (Table 1). Fifth, the orientation of dendrites andthe dendritic radius of neurons in the subthalamic nucleus (alsosee Kita et al., 1983) is such that they cross functional boundarieswithin the nucleus and indeed receive synaptic input from terminalsderived from the pallidal complex along their whole length (asfar as 330 µm from the perikaryon), indicating that convergentinput also occurs at the level of dendrites (also see Shink andSmith, 1995b). A similar organization of dendrites has been reportedfor the entopeduncular nucleus (Nakanishi et al., 1991) and thesubstantia nigra pars reticulata (Grofova et al., 1982).
Fig. 10. Schematic summary of the somatic and dendritic modes of synaptic integration of descending, functionally distinct pallidalprojections in the subthalamic nucleus revealed by double anterogradelabeling and electron microscopy. The pallidal complex providesprojections to the subthalamic nucleus that largely maintain thefunctional topography. Adjacent populations of neurons, illustratedby PALLIDAL ZONE A and PALLIDAL ZONE B and giving rise to blackand white boutons, respectively, although mainly innervating separatebut adjacent regions of the subthalamic nucleus, also give riseto a region of overlap. The dimensions and orientation of dendritesof a large proportion of neurons in the subthalamic nucleus aresuch that they extend in a mediolateral or ventrodorsal directionand thus cross the functional boundaries defined by the pallidalinputs. Integration of the descending, functionally diverse informationfrom the pallidal complex occurs by synaptic convergence on individualneurons in the subthalamic nucleus. This is mediated by two systems:synaptic integration at the level of the soma and proximal dendrites,and synaptic integration at the level of more distal dendrites.Synaptic integration of pallidal inputs occurs at the level ofthe soma and proximal dendrites of neurons located in the regionof overlap of the pallidal projections (middle neuron). Theseneurons receive synaptic input to their cell bodies and proximaldendrites from neurons located in both pallidal zones. Their distaldendrites, if oriented across the boundaries, will also receiveinputs from both pallidal zones. The net weights of the two pallidalinputs to these neurons are likely to be similar, although thedistal dendrites will preferentially receive inputs from one orthe other of the pallidal zones. The second mode of synaptic integrationoccurs on the distal dendrites of neurons, the cell bodies ofwhich are located within a functional zone defined on the basisof its pallidal input (top and bottom neurons in the diagram).A high proportion of the pallidal input to these neurons is derivedfrom the single pallidal zone (PALLIDAL ZONE A or B) that providesthe innervation of the functional zone (FUNCTIONAL ZONE A or B)within which they reside. The dendrites that cross functionalboundaries, however, receive synaptic input from the topographicallyadjacent pallidal zone in the region of overlap and in the adjacentfunctional zone of the subthalamic nucleus. In this case the pallidalinput will be weighted in favor of the pallidal region that projectsto the zone within which the neuron (mainly) resides, but willvary with the position of the neurons in relation to the boundariesand the number of dendrites crossing the boundary. In this systemalso, it is possible that individual dendrites will receive inputsfrom a single pallidal zone. The data on which this model is basedwere derived from injections of tracers into broad functionalzones of the pallidal complex, i.e., the limbic division (ventralpallidum) and the motor and associative division (globus pallidus)that nevertheless give rise to adjacent projections. Topographicstudies suggest that these broad functional zones are themselvessubdivided into small groups of functionally related neurons thatare organized into multiple parallel pathways. We predict thatthe same principles of organization will apply to these subdivisionsof the pallidal complex. Although the present model is based mostlyon findings of neurons in the subthalamic nucleus, the presentwork and previously published data (Bevan et al., 1996) indicatethat the somatic integration in areas of overlap of pallidal projectionsalso occurs in the entopeduncular nucleus, the lateral hypothalamus,and the substantia nigra pars reticulata. Furthermore, the synaptologyof the pallidal projections and the synaptology and orientationof dendrites in these regions indicate that integration also probablyoccurs at the level of distal dendrites (see text for references).Although synaptic convergence of functionally diverse pallidalinputs also occurs on dopamine neurons of the substantia nigrapars compacta and the ventral tegmental area (Bevan et al., 1996),the exact rules of synaptic integration remain to be established.
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The present observations together with data from other tracing studies (Smith et al., 1990; Smith and Bolam, 1991; Bolam andSmith, 1992; Bolam et al., 1993; Bevan et al., 1994a,b; Smithet al., 1994; Shink and Smith, 1995a; Bevan et al., 1996; Shinket al., 1996) lead us to conclude that functionally diverse informationcarried by the descending projections of the pallidal complexis synaptically integrated by two mechanisms (Fig. 10). First,neurons located at the interface between functionally distinctbut topographically adjacent projections integrate the diversefunctional information at the level of the cell body and proximaldendrites. Second, the orientation and dimensions of dendritesin relation to the topography of the pallidal inputs to the subthalamicnucleus and the distribution of the pallidal inputs along thedendrites of subthalamic neurons imply that integration of pallidalinformation also occurs at the level of their more distal dendrites.In view of the distribution of postsynaptic targets of terminalsderived from the pallidal complex in the entopeduncular nucleusand the substantia nigra pars reticulata (Table 1), and the morphologyand orientation of dendrites of entopeduncular and nigral neurons,it is likely that this mode of synaptic integration of functionallydiverse pallidal information also occurs in these two regions(Fig. 10). Because synaptic input to the perikaryon is likely tohave a more marked effect on the activity of neurons than inputsto distal dendrites, the pallidal input to the region in whichthe perikaryon of the target neuron lies may have a greater influenceon the activity of the neuron than the pallidal input to the distaldendrites, although their pattern of activity and the distributionand types of GABA receptors on these neurons will also be a factors.

The conclusions of our studies are dependent on two issues: first, the technical issues relating to the use of double anterogradelabeling techniques at both the light and electron microscopiclevels. These issues have been discussed extensively on previousoccasions and so will not be dealt with here (Smith and Bolam,1991, 1992; Bolam and Smith, 1992; Bolam et al., 1993). The secondissue relates to the functionality of the regions of the pallidalcomplex that we injected. It is well recognized that the functionalityof different regions of the pallidal complex is dependent on itsinput from the striatal complex and ultimately on the source ofinnervation of that region of the striatal complex. Thus the regionsof the pallidal complex that we injected, the ventral pallidumand the globus pallidus, receive their major input from the nucleusaccumbens and the dorsal striatum, respectively. The nucleus accumbensin turn receives major inputs from limbic regions of the brain,including the hippocampus and the amygdala, whereas the majorinput to the dorsal striatum is from motor and associative regionsof the cortex (Kunzle, 1975; Goldman and Nauta, 1977; Van Hoesenet al., 1981; Nauta and Domesick, 1984; Selemon and Goldman-Rakic,1985; Alexander et al., 1986, 1990; McGeorge and Faull, 1989;Flaherty and Graybiel, 1991; Hoover and Strick, 1993; Groenewegenand Berendse, 1994; Joel and Weiner, 1994). Thus the ventral pallidumis recognized as the limbic division of the pallidal complex,and the globus pallidus as the motor and associative division.We ensured that our deposits of tracers were confined to eitherthe ventral pallidum or the globus pallidus by comparing the locationof the deposits with the region of dense substance P immunoreactivity,which is a marker for the ventral pallidum (Haber and Nauta, 1983;Groenewegen et al., 1993), and by comparing the distribution ofneurons in the striatal complex that became retrogradely labeledafter the tracer deposits in the pallidal complex (Fig. 3). Thelatter observation not only confirmed that the location of thedeposits lay within the ventral pallidum or the globus pallidus,but also confirmed that the areas that received the deposits wereprobably functionally distinct in that they received input fromthe nucleus accumbens and the dorsal striatum, respectively.

Functional considerations
An issue that has been the subject of much debate is the nature of information processing by the basal ganglia. Concepts ofmultiple, parallel, functionally segregated pathways of information-flowthrough the basal ganglia, as opposed to concepts of convergenceand integration, have been proposed (Francois et al., 1984; Percheronet al., 1984, 1987; Alexander et al., 1986, 1990; Flaherty andGraybiel, 1991, 1993, 1994; Percheron and Filion, 1991; Parthasarathyet al., 1992; Hoover and Strick, 1993; Groenewegen and Berendse,1994; Joel and Weiner, 1994; Lynch et al., 1994). From tracingstudies it is evident that there is a functional topography thatis maintained throughout the cortico-basal ganglia-thalamocorticalsystem; however, it is also clear from behavioral and physiologicalanalyses and from clinical data that one of the functions of thebasal ganglia is to integrate diverse information in the productionof context-dependent behavior (Wurtz and Hikosaka, 1986; Schultzet al., 1993; Graybiel et al., 1994; Aosaki et al., 1995). Mostauthors agree that synaptic convergence does occur, and the numberof neurons in each nucleus of the basal ganglia (Oorschot, 1996)indicates that there is a high degree of convergence in the systemwe have analyzed and in the basal ganglia in general. Such convergencecould be between neurons at each level within one of the functionallydistinct parallel pathways that may mediate the convergence ofinformation related in different ways to the common goal of controllinga particular movement, behavior, or cognitive process. Indeed,the elegant studies of Graybiel and colleagues (Flaherty and Graybiel,1991, 1993, 1994; Parthasarathy et al., 1992) show clearly thatin the corticostriatal system, groups of neurons in motor andsomatosensory cortices that are related to a particular body partprovide overlapping (and presumably synaptic convergent) projectionsto specific regions of the neostriatum. It has also been suggested,however, that the organization of the striatopallidal system andthe organization of dendrites in the globus pallidus provide asubstrate for synaptic integration of widely diverse functionalinformation arising from the neostriatum (Francois et al., 1984;Percheron et al., 1984, 1987; Percheron and Filion, 1991), althoughthere is no evidence as yet at the synaptic level. The ascendingdopaminergic system may underlie a similar role (Somogyi et al.,1981; Nauta and Domesick, 1984; Gerfen et al., 1987; Jimenez-Castellanosand Graybiel, 1987; Smith and Bolam, 1990). Our data provide thefirst direct evidence of an anatomical substrate at the synapticlevel for the convergence of functionally diverse informationby a descending projection system in the basal ganglia. It isunclear at present whether within this system or as part of thissystem there is also synaptic convergence of small groups of neuronsrelated in different ways to a common goal of controlling a particularprocess.

An important principle emerges from the topographical organization of the descending projection of the pallidal complex (Alexanderet al., 1986, 1990; Smith and Bolam, 1989, 1991; Groenewegen etal., 1993; Hoover and Strick, 1993; Groenewegen and Berendse,1994; Joel and Weiner, 1994; Lynch et al., 1994). Convergent pallidalinput to the proximal regions of neurons in the subthalamic nucleus(and other nuclei of the basal ganglia) probably arises from pallidalneurons that are closely spaced and presumably more closely relatedin functional terms. Convergent input to more distal dendritesprobably arises from pallidal neurons that are more widely spacedand therefore presumably more widely separated in functional terms.It remains to be established whether pallidal inputs located ondifferent parts of the soma and dendritic tree have differenteffects on the firing or activity of the postsynaptic neuron.The findings of pallidal inputs to the distal dendrites of neuronsin the subthalamic nucleus and the fact that the orientation oftheir dendrites are such that they cross functional boundariesdefined by the pallidal input implies that convergence of functionallydiverse information occurs more commonly than can be surmisedfrom the degree of overlap of the projections.

The precise role of neurons of the pallidal complex remains unclear. They are part of the neuronal network of the so-called"indirect pathway" and as such are involved in the resting inhibitoryoutput of the basal ganglia and presumably the periods of inhibitionof basal ganglia targets that occur during complex behaviors (Albinet al., 1989; Alexander and Crutcher, 1990; DeLong, 1990; Gerfenand Wilson, 1996; Shink et al., 1996). Our data indicate thatactivity in the indirect pathway is probably important in theintegration of functionally diverse information. The parallelbut distributed and partly convergent network of the descendingprojections of the pallidal complex provides an anatomical basisfor the association of functionally diverse information that maybe of importance in the production of integrated behavior andlearning.

Concluding remarks
Our confirmation of the topography of the descending projections of the pallidal complex and the findings of synaptic convergencereconcile the two opposing views of segregation and integration.The findings emphasize the point that when considering the topographicaland functional organization of the basal ganglia, we must considernot only the topography of projections but also the arrangementof dendrites and the synaptic organization of both the projectionaxons and the neurons in the target regions. Our results and thoseof others demonstrate that within the basal ganglia, systems forparallel channels, systems for the synaptic integration of closelyrelated information, and systems for the synaptic integrationof functionally diverse information coexist.

FOOTNOTES

Received Aug. 13, 1996; accepted Oct. 2, 1996.

This work was funded by the Wellcome Trust and the Medical Research Council, United Kingdom. N.P.C. is in receipt of a MedicalResearch Council Studentship; M.D.B. is in receipt of a WellcomeTrust Advanced Training Fellowship (046613/2/96/2). We thank CarolineFrancis, Paul Jays, Frank Kennedy, and Liz Norman for technicalassistance, Peter Somogyi for the GABA antiserum, Claudio Cuellofor the antibodies to substance P, Véronique Bernard and JasonHanley for comments on this manuscript, and David Smith for helpfuldiscussions throughout the period of the work.

Correspondence should be addressed to J. P. Bolam, Medical Research Council Anatomical Neuropharmacology Unit, UniversityDepartment of Pharmacology, Mansfield Road, Oxford OX1 3TH, UK.

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Volume 17, Number 1, Issue of January 1, 1997 pp. 308-324 Copyright ©1997 Society for Neuroscience

Synaptic Integration of Functionally Diverse Pallidal Information in the Entopeduncular Nucleus and Subthalamic Nucleus in the Rat

Volume 17, Number 1, Issue of January 1, 1997 pp. 308-324
Copyright ©1997 Society for Neuroscience