Synaptic Convergence of Motor and Somatosensory Cortical Afferents onto GABAergic Interneurons in the Rat Striatum

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The Journal of Neuroscience, September 15, 2002, 22(18):8158-8169

Synaptic Convergence of Motor and Somatosensory Cortical Afferents onto GABAergic Interneurons in the Rat Striatum
Sankari Ramanathan¹, Jason J. Hanley¹, Jean-Michel Deniau², and J. Paul Bolam¹
¹ Medical Research Council Anatomical Neuropharmacology Unit, Department of Pharmacology, Oxford, OX1 3TH, United Kingdom, and ² Institut National de la Santé et de la Recherche Médicale U114, Collège de France, 75321 Paris Cedex 05, France

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cortical afferents to the basal ganglia, and in particular the corticostriatal projections, are critical in the expressionof basal ganglia function in health and disease. The corticostriatalprojections are topographically organized but also partially overlapand interdigitate. To determine whether projections from distinctcortical areas converge at the level of single interneurons inthe striatum, double anterograde labeling from the primary motor(M1) and primary somatosensory (S1) cortices in the rat, was combinedwith immunolabeling for parvalbumin (PV), to identify one populationof striatal GABAergicinterneurons.
Cortical afferents from M1 and S1 gave rise to distinct, but partially overlapping, arbors of varicose axons in the striatum.PV-positive neurons were often apposed by cortical terminals and,in many instances, apposed by terminals from both cortical areas.Frequently, individual cortical axons formed multiple varicositiesapposed to the same PV-positive neuron. Electron microscopy confirmedthat the cortical terminals formed asymmetric synapses with thedendrites and perikarya of PV-positive neurons as well as unlabelleddendritic spines. Correlated light and electron microscopy revealedthat individual PV-positive neurons received synaptic input fromaxon terminals derived from both motor and somatosensorycortices.
These results demonstrate that, within areas of overlap of functionally distinct projections, there is synaptic convergenceat the single cell level. Sensorimotor integration in the basalganglia is thus likely to be mediated, at least in part, by striatalGABAergic interneurons. Furthermore, our findings suggest thatthe pattern of innervation of GABAergic interneurons by corticalafferents is different from the cortical innervation of spinyprojectionneurons.

Key words: GABA; striatum; corticostriatal; parvalbumin; cortex; basal ganglia

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The basal ganglia are a group of subcortical nuclei that are intimately involved in the control of movement. One of theirmajor roles is to integrate sensory, motor, associative, and limbicinformation in the production of context-dependent behaviors (Graybiel,1990, 1995). Anatomical and physiological data suggest that corticalinformation transmitted to the basal ganglia via the corticostriatalprojection is channeled into parallel functional circuits thatremain segregated at each level of the corticobasal ganglia-thalamo-corticalloops (Alexander et al., 1986, 1990; Alexander and Crutcher, 1990;DeLong, 1990; Hoover and Strick, 1993; Parent and Hazrati, 1995;Middleton and Strick, 2000). In addition to this organizationunderlying "parallel processing", the possibility for integrationof diverse information within, and between, these loops also exists(Nauta and Domesick, 1984; Francois et al., 1987; Flaherty andGraybiel, 1991, 1993, 1995; Parthasarathy et al., 1992; Graybiel,1995; Beiser et al., 1997; Maurin et al., 1999; Haber et al.,2000; Hoffer and Alloway, 2001; Kolomiets et al., 2001). Indeed,anatomical substrates that may underlie the integration of diverseinformation within the basal ganglia at the synaptic level havebeen identified (Somogyi et al., 1981b; Bevan et al., 1996, 1997).For instance, neurons of the substantia nigra pars compacta thatproject to the dorsal (motor and associative) striatum receivesynaptic input from neurons located in the ventral (limbic) striatum(Somogyi et al., 1981b). Similarly, although there is a cleartopography of the caudal projections of the ventral pallidum (limbic)and the globus pallidus (motor and associative), there are regionsof overlap in the substantia nigra, subthalamic nucleus, and entopeduncularnucleus where synaptic convergence of the two divisions of thepallidal complex occurs at the single cell level (Bevan et al.,1996, 1997).

The striatum is also a site of functional convergence. Although the corticostriatal projections are highly topographicallyorganized, they partially overlap and interdigitate (Malach andGraybiel, 1986; Gerfen, 1989; Flaherty and Graybiel, 1991, 1993,1995; Parthasarathy et al., 1992; Brown et al., 1998; Takada etal., 1998; Hoffer and Alloway, 2001). Anatomical data suggeststhat corticostriatal projections from reciprocally connected corticalregions are more likely to have overlapping arborizations withinthe striatum (Yeterian and Van Hoesen, 1978; Pearson et al., 1983;Flaherty and Graybiel, 1993). Furthermore, projections from functionallyrelated, but distinct, cortical regions (primary motor and primarysomatosensory cortices) have been shown to converge in the striatum(Flaherty and Graybiel, 1993; Hoffer and Alloway, 2001). Electrophysiologicalanalyses have shown striatal neurons to respond to both somatosensoryand auditory stimuli in rats (Chudler et al., 1995) and to tactile,auditory, and visual stimuli in cats (Wilson et al., 1983b; Schneider,1991).

The main target of corticostriatal terminals are the spines of the GABAergic medium spiny projection neurons (Kemp and Powell,1971b; Frotscher et al., 1981; Somogyi et al., 1981a; Dubé etal., 1988; Smith et al., 1994) and the cortical input shapes theactivity of these neurons (Wilson et al., 1983a; Wilson, 1995;Wilson and Kawaguchi, 1996; Mahon et al., 2001). The second majortarget of the cortical input to the striatum is the class of GABAergicinterneuron (Lapper et al., 1992; Bennett and Bolam, 1994) thatexpresses the calcium-binding protein parvalbumin (PV) (Cowanet al., 1990; Kita et al., 1990). The major target of these interneuronsare the proximal regions of spiny projection neurons, and an individualinterneuron may contact many hundreds of spiny neurons (Cowanet al., 1990; Kita et al., 1990; Kita, 1993; Bennett and Bolam,1994). It has been proposed that they provide a feedforward inhibitorycontrol of spiny neurons (Pennartz and Kitai, 1991; Jaeger etal., 1994; Kita, 1996; Plenz and Kitai, 1998) and indeed, theygenerate inhibitory synaptic potentials that are able to delay,curb, or possibly synchronize, the generation of action potentialsin spiny projection neurons (Koos and Tepper, 1999).

In view of the critical position of PV-positive, GABAergic interneurons in the circuitry of the striatum and the fact thatthey are activated more easily and over a larger volume of striatumafter cortical stimulation than are spiny neurons (Parthasarathyand Graybiel, 1997), we chose to analyze the cortical input tothese neurons. Thus, the aims were to determine whether corticalafferents from the primary motor cortex (M1) and primary somatosensorycortex (S1) converge on individual PV-positive interneurons andto provide insight into the pattern of innervation of these neuronsby individual corticalaxons.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Surgery. The experiments were performed on adult female Wistar rats (200-350 gm; Charles River, Margate, Kent, UK). Environmentalconditions for housing of the rats and all procedures that wereperformed on them were in accordance with the Animals (ScientificProcedures) Act of 1986 and the policy on the use of animals issuedby the Society for Neuroscience. Twelve rats were anesthetizedby intraperitoneal injections of a mixture of fentanyl and fluanisone(0.135 mg/ml and 10 mg/ml, respectively; Hypnorm; Janssen-CilagLtd., High Wycombe, UK) and midazolam (5 mg/ml; Hypnovel; RocheProducts Ltd., Welwyn Garden City, UK) (1:1:2 with sterile water:2.7 ml/kg) and the head secured in a stereotaxic frame. The animalsreceived unilateral deposits of Phaseolus vulgaris leucoagglutinin[PHAL; 2.5% in 0.1 M phosphate buffer (PB), pH 8.0; Vector Laboratories,Peterborough, UK] in the primary motor cortex and biotinylateddextran amine (BDA; 10% in 0.9% NaCl; Molecular Probes, Eugene,OR) in the primary somatosensory cortex. The anterograde tracerswere delivered by iontophoresis via glass micropipettes of 7-50µm internal tip diameter using a pulsed (7 sec on/7 sec off) positivecathodal current (7-10 µA) over 10-15 min. Three deposits weremade in each region. After a survival time of 5-8 d, the ratswere deeply anesthetized with sodium pentobarbital (Sagatal, 200mg/kg; Rhône Mérieux, Tallaght, Dublin) and perfused transcardiallywith 50-100 ml of PBS (0.01 M, pH 7.4) followed by 300 ml of 0.1-0.2%glutaraldehyde and 3% paraformaldehyde in 0.1 M PB. Some animalswere post-perfused with ~100 ml ofPBS.

Preparation of tissue for light microscopy. Coronal sections of the tracer injection sites, thalamus, and striatum were cuton a vibrating microtome at 70 µm. Sections were incubated for30 min in 0.3% Triton X-100 in PBS (PBST), washed in PBS, andthen treated with 1% bovine serum albumin and 1% normal goat serumin PBS (PBS-BSA) for 2 hr at room temperature. The injected andtransported BDA was revealed using the avidin-biotin-peroxidasecomplex method (ABC; 1:100 in PBST-BSA; Vector Laboratories) with3,3'-diaminobenzidine (DAB; 25 mg/100 ml Tris buffer; Sigma, Dorset,UK; 0.006% H₂O₂) as the chromogen for the peroxidase reaction.To reveal the injected and transported PHAL, sections were incubatedovernight in rabbit anti-PHAL (1:1000 in PBST-BSA; Vector Laboratories),treated with goat anti-rabbit IgG (1:200 in PBST-BSA; Dako, HighWycombe, UK) for 2 hr, followed by a 1 hr incubation in rabbitperoxidase-antiperoxidase (PAP) (1:100 in PBST-BSA; Dako), allat room temperature. The bound peroxidase was then revealed withDAB in the presence of nickel ions (nDAB). In some animals theBDA was revealed with nDAB and the PHAL with DAB. Parvalbumin-immunoreactivestructures were revealed by incubation in mouse anti-PV (1:1000in PBST-BSA; Swant, Bellinzona, Switzerland) for 24-36 hr at 4°Cfollowed by goat anti-mouse IgG (1:200 in PBST-BSA; Jackson ImmunoResearch,West Grove, PA) for 2 hr at room temperature and mouse PAP (1:100;Dako) with Vector SG as chromogen for the peroxidasereaction.

Preparation of tissue for electron microscopy. The striata of six animals were processed for electron microscopy. To increasethe penetration of reagents, the sections were freeze-thawed inisopentane (BDH Chemicals, Poole, UK) cooled in liquid nitrogenup to three times. The sections were washed several times in PBSbefore the tracers and parvalbumin-immunoreactive structures wererevealed. The method was as described above with the omissionof Triton X-100 from all solutions. The labeled sections of thestriatum were postfixed in 1% osmium tetroxide (Oxkem), 5% $beta$ -D-glucose(BDH Chemicals) in 0.1 M PB at pH 7.4 for 60-70 min. (Acsady etal., 1996). The sections were dehydrated through a graded seriesof dilutions of acetone (with 1% uranyl acetate in the 70% solution)and infiltrated with resin overnight (Durcupan; Fluka Chemicals).They were then mounted in resin on glass microscope slides andpolymerized at 60°C for 48hr.

Analysis of material. All sections containing the sites of injection of the tracers were examined to ensure that they werecorrectly placed. The locations of the injection sites were alsoconfirmed by analysis of sections of the thalamus for anterogradelyand retrogradely labeled structures. Sections of the striatumfrom those animals in which the injections were correctly locatedwere examined in the light microscope for the anterograde tracersand PV immunoreactivity. In some animals the anterograde labelingwas plotted and recorded schematically. Particular attention waspaid to regions of overlap of the two tracers. In these areas,PV-immunoreactive neuronal perikarya and emerging dendrites wereexamined at high magnification, and the positions of anterogradelylabeled terminals closely apposed to them was noted. In some casesPV-positive neurons and individual cortical axons were drawn withthe aid of a drawing tube and photographeddigitally.

In a semiquantitative analysis, a single section of the striatum from three rats that were prepared for light microscopy (i.e.,Triton X-100 included in the incubations) were analyzed at highmagnification. The selected sections were those in which the regionof overlap of the anterograde labeling from the two regions ofthe cortex was the most extensive. The location of each PV-positiveperikaryon and emerging dendrites was noted. The proportion apposedby anterogradely labeled terminals derived from either regionof the cortex wasnoted.

From the tissue that was processed for electron microscopy, eight PV-immunoreactive neurons (from four animals) whose cellbodies and/or dendrites were identified as being apposed by anterogradelylabeled terminals from both regions of the cortex in the lightmicroscope, were selected for further study. The cells were drawnand photographed at high magnification and examined by correlatedlight and electron microscopy. The coverslip overlying the tissuewas removed using a razor blade. The area of interest was cutfrom the microscope slide and glued to the top of a blank cylinderof resin using cyanoacrylate glue. Serial ultrathin sections of40-60 nm thickness were cut on a Reichert-Jung Ultracut E ultramicrotome(Leica, Nussloch, Germany) and collected on Pioloform-coated singleslot copper grids. The ultrathin sections were then contrastedwith lead citrate for 2-3 min and examined in a Philips CM 10electronmicroscope.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Light microscopic observations

Appearance of the reaction products
The anterogradely labeled and immunolabeled structures were visualized with different chromogens for the peroxidase reactionsthat were distinguishable at the light microscopic level. Structuresvisualized with DAB as the chromogen for the peroxidase reactionwere characterized by the presence of the typical reddish brownamorphous reaction product (see Fig. 3), and those visualizedwith nDAB contained the typical blue-black reaction product (seeFig. 3). Parvalbumin-immunoreactive structures were visualizedusing Vector SG as the chromogen and were characterized by thepresence of a grayish blue reaction product that was less homogeneousthat the DAB reaction products (see Fig. 3). The use of osmiumtetroxide solution supplemented with glucose maintained colorseparation, at the light microscopic level, between differentreaction products in the sections that were prepared for examinationby both light and electron microscopy (Acsady et al., 1996) (seeFigs. 5D, 6A,D).

Injection sites
The location of the injection sites of the two anterograde tracers (PHAL and BDA) was confirmed by visualization of the tracersin the M1 and S1 cortices (Figs. 1, 2). In the majority of casesthe deposits of the two tracers were clearly separated. They spannedmost of the cortical laminas without inclusion of the underlyingcorpus callosum. In some cases there were retrogradely labeledneurons of S1 close to the M1 injection site. However, these retrogradelylabeled neurons were clearly separate from the filled neuronsat the injection site; they constituted only very few neuronsand were thus unlikely to influence the findings.

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Figure 1. Schematic representations (modified from Paxinos and Watson, 1997) of the sites of injection of PHAL in M1 (vertical hatching) and BDA in S1 (horizontal hatching) and the corresponding labeling in the thalamus in the three animals used in the electron microscopic analysis. The deposits of PHAL were confined to frontal cortex areas 1 and 3 with a slight encroachment in area 2. In each animal the thalamic labeling was confined to the ventrolateral nucleus of the thalamus. The BDA deposits were confined to parietal cortex, area 1, and labeling in the thalamus was confined to the lateral and medial aspects of the posterior nucleus. The figures denote the position in millimeters with respect to bregma (Paxinos and Watson, 1997). VL, Ventrolateral nucleus of thalamus; VM, ventromedial nucleus of thalamus; VPL, lateral aspect of ventroposterior nucleus of thalamus; VPM, medial aspect of ventroposterior nucleus of thalamus.

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Figure 2. Schematic representations (modified from Paxinos and Watson, 1997) of the sites of injection of PHAL in primary motor cortex (M1) and BDA in the primary somatosensory cortex (S1), the corresponding labeling in the thalamus and the anterograde labeling in the striatum (caudate-putamen; CPu). In each diagram the PHAL injection and the corresponding transport sites are indicated by vertical hatching, and the BDA injection and transport sites are indicated by horizontal hatching. The figures denote the position in millimeters with respect to bregma (Paxinos and Watson, 1997).

The location of the injections was confirmed by the analysis of the coincidental anterograde and retrograde labeling of thalamicnuclei. The motor cortex is innervated by thalamocortical projectionsmainly from the ventromedial and ventrolateral thalamic nucleiand in turn sends projections back to these motor nuclei (Cicirataet al., 1986, 1990). The somatosensory cortex is reciprocallyconnected to the ventrobasal nuclei, the intralaminal nucleuscentralis lateralis, and the medial portion of the posterior thalamicgroup (Price and Webster, 1972; Nothias et al., 1988; Bourassaand Deschenes, 1995). In four of the six animals prepared forelectron microscopy the labeling of thalamic nuclei was distinctfor both the injection sites, and cells from these animals werestudied at the ultrastructural level. In the remaining two animalsthere was clearly an overlap of the two injection sites in thedifferent cortical territories as indicated by the thalamic labeling,these animals, and those prepared for light microscopy in whichoverlap of injections occurred, were excluded from theanalysis.

Distribution of anterograde labeling
The deposits of PHAL and BDA in the M1 and S1 cortices, respectively, led to intense labeling of corticostriatal projectionsthat were topographically organized and largely consistent withprevious observations. The corticostriatal axons were collectedin the fascicles of axon bundles traversing the striatum, andaxonal arbors were primarily located around the fiber fascicles.The typical pattern of innervation of the striatum from M1 isillustrated in Figure 2. Anterogradely labeled fibers occurredin a band of striatum extending from ~1.6 mm rostral of bregmato ~1.3 mm caudal of it. Anterograde labeling from S1 occurredin a band in the lateral aspects of the striatum extending from~1.2 mm rostral of bregma to ~2.3 mm caudal. The band extendedover a large part of the striatum in the dorsoventral plane and,at its maximum extent, occupied approximately one-third of thestriatum in the mediolateral plane (Fig. 2).
A large part of the more lateral and caudal aspects of the projection from M1 overlapped with the projection from S1. In theseregions the two sets of anterogradely labeled terminals were intermixedto such an extent that axonal varicosities derived from the differentcortical territories were often observed in close proximity (Figs.3, 4B, 5A,D, 6A,D).

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Figure 3. Light microscopy of convergence of motor and somatosensory afferents in the striatum: parvalbumin-immunostained perikarya (PV) and axons anterogradely labeled with PHAL from M1 and axons anterogradely labeled with BDA from S1. In these cases the PHAL-containing motor cortical fibers were revealed using DAB as the chromogen for the peroxidase reaction giving a brown reaction product. The BDA-containing axons were labeled with nickel DAB as the chromogen giving the blue reaction product. These digital images and those in Figures 5, A and D, and 6, A and D, were prepared from scanned images of color photomicrographs and have been color balanced in Adobe Photoshop 6.0. They are derived from sections that were prepared for light microscopic analysis only. A, This parvalbumin-immunolabeled neuron (PV)is in a region containing many PHAL- and BDA-labeled axons, many of which are closely apposed to the labeled neuron. At this focal depth there are several BDA-labeled boutons apposed to the perikaryon and proximal dendrite, and a PHAL-labeled bouton also closely apposes the dendrite. B, Montage of a second parvalbumin-immunolabeled neuron (PV) that is apposed by boutons derived from the motor cortex (PHAL) and somatosensory cortex (BDA). Note that the PHAL-labeled axon gives rise to several boutons that are apposed to the PV-positive perikaryon. Scale bars, 10 µm.

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Figure 4. Light microscopic digital images and corresponding camera lucida drawings of striatal parvalbumin-positive neurons and individual cortical axons forming multiple appositions. A, B, Digital montage (A) and drawing (B) of a parvalbumin-positive interneuron and anterogradely labeled cortical fibers in the striatum. The PV-positive neuron gave rise to several immunolabeled dendrites, one of which was closely apposed by an axon anterogradely labeled with BDA from the somatosensory cortex. The axon gave rise to six varicosities that closely apposed the dendrite (small arrows, 1-6), five of which are visible in the light micrograph (1-5). The neuron was also apposed by two varicosities of an axon anterogradely labeled from the motor cortex that is not visible at the focal depth of the micrograph but is shown in the drawing (two arrows, top right). C, D, A parvalbumin-positive neuron apposed by an axon anterogradely labeled with PHAL from the motor cortex. The axon give rise to five boutons that closely appose the dendrites and perikaryon of the labeled neuron. E, F, A parvalbumin-positive neuron apposed by an axon anterogradely labeled with BDA from the somatosensory cortex. The axon gave rise to five boutons that closely apposed the perikaryon and dendrites of the labeled neuron. Scale bars: A, C, E, 10 µm; B, D, F, 10 µm.

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Figure 5. Synaptic convergence of motor and somatosensory cortical afferents onto a parvalbumin-positive, GABAergic interneuron in the striatum: correlated light and electron microscopy. A, Light micrograph of a parvalbumin-immunostained neuron (PV) labeled using Vector SG as the substrate for the peroxidase reaction. The neuron was located in a region containing fibers anterogradely labeled with PHAL from the motor cortex (PHAL, nDAB as chromogen; blue fiber indicated by small arrows on the left) and with BDA from the somatosensory cortex (BDA, DAB as chromogen; brown fiber indicated by small arrows on the right). The axon from the somatosensory cortex gives rise to several varicosities, one of which closely apposes the perikaryon (BDA, large arrow). The capillary (c) is labeled as a landmark between the light and electron microscopic levels. B, Low-power electron micrograph of part of the same perikaryon and the BDA-labeled, somatosensory cortical bouton closely apposed to it (BDA, arrow). C, High-power electron micrograph of the BDA-labeled bouton from the somatosensory cortex. The labeled terminal forms an asymmetrical synaptic contact (arrowhead) with the parvalbumin-immunolabeled neuron. D, Digital light micrograph of the same parvalbumin-immunolabeled neuron (PV) at a deeper focal depth. At this level the neuron is apposed by a PHAL-positive bouton (PHAL, arrow) derived from the motor cortex. E, Low-power electron micrograph at about the same level as in D. The perikaryon, part of a dendrite, and the PHAL-labeled bouton derived from the motor cortex are present. Note the position of the capillary (c) for correlation between light and electron microscopic levels. The immunostained neuron possesses an intranuclear inclusion (small arrow), a feature typical of GABAergic interneurons in the striatum. F, High-power electron micrograph of the PHAL-positive bouton forming an asymmetrical synaptic contact (arrowhead) with the parvalbumin-positive dendritic shaft. Note that the reaction product formed by the nDAB is more intense than that formed by the DAB as seen in C. Two unlabelled axonal boutons are indicated by asterisks. Scale bars: A, D, 12.5 µm; B, E, 5 µm; C, F, 0.25 µm.

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Figure 6. Synaptic convergence of motor and somatosensory cortical afferents onto a parvalbumin-immunolabeled, GABAergic interneuron in the striatum: correlated light and electron microscopy. A, Light micrograph of a parvalbumin-positive neuron (PV; Vector SG as chromogen for the peroxidase reaction) that is closely apposed by a BDA-positive bouton (BDA, arrow) that was anterogradely labeled from the somatosensory cortex (DAB as chromogen for the peroxidase reaction, brown reaction product). Note the additional axon anterogradely labeled from the somatosensory cortex in the top right of the micrograph (small arrows). An unstained neuron (n) and a capillary (c) are labeled for correlation between the light and electron microscopic levels. B, Low-power electron micrograph of the same neuron and the bouton anterogradely labeled with BDA from the somatosensory cortex. C, High-power electron micrograph of the PHAL-labeled bouton forming an asymmetric synapse (arrowhead) with the parvalbumin-positive neuron. D, The same neuron at a deeper focal depth. The proximal dendrite of the neuron is apposed by two boutons (b1 and b2), derived from two axons that were anterogradely labeled with PHAL from the motor cortex. E, Low-power electron micrograph at about the same level, of the perikaryon and dendrite and the two PHAL-labeled boutons from the motor cortex. The unstained neuron (n) and capillary (c) are labeled for correlation between the light and electron microscopic levels. F, High-power electron micrograph of the two PHAL-positive boutons derived from the motor cortex, forming asymmetric synapses (arrowheads) with the proximal dendrite of the parvalbumin-positive, GABAergic interneuron. Scale bars: A, D, 12.5 µm; B, E, 5 µm; E, F, 0.5 µm.

Parvalbumin-positive GABAergic interneurons
Parvalbumin-positive interneurons were identified by the gray reaction product formed by the Vector SG. Perikarya and proximaldendrites, as well as isolated dendrites, were labeled. Theirmorphology and distribution were consistent with previous studies(Cowan et al., 1990; Kita et al., 1990; Bennett and Bolam, 1994).The labeled neurons had medium-sized cell bodies, which were oval,or fusiform in shape. In some cases, indentations of the nuclearmembrane were visible. Labeled primary dendrites branched closeto the cell body and the secondary dendrites were generally smoothbut sometimes gave rise to varicosities (Figs. 3, 4). Higher orderdendrites were usually not labeled. The heaviest labeling of PV-positivestructures was in the dorsolateral aspect of the striatum. Althoughthe striatum is known to possess a dense network of PV-positivelocal axons and axonal boutons, PV-positive axonal fields wereusually not labeled in the present study. This may reflect thesensitivity of the chromogen used and the fact that the immunostainingfor PV was performedlast.

Light microscopic analysis of convergence of cortical terminals on PV-positive neurons
Parvalbumin-positive neuronal perikarya and dendrites were intermingled among axons and axonal boutons anterogradely labeledfrom both M1 and S1 cortices (Fig. 3). The PV-positive structureswere often closely apposed by the anterogradely labeled boutons,consistent with previous observations of cortical input to thisclass of neuron (Lapper et al., 1992; Bennett and Bolam, 1994).In many cases, an individual PV-positive neuronal perikaryon orisolated dendrite was closely apposed by terminals anterogradelylabeled from M1 and terminals anterogradely labeled from S1 (Fig.3). Examination of all PV-positive perikarya and emerging dendrites(but not isolated dendrites) in single sections at the level ofthe greatest extent of overlap of the two projections, revealedthat up to 51% (range, 35.4-50.9) of PV-positive neurons wereapposed by terminals derived from the cortex. Up to 46% (range,24.7-46.2) of those that were apposed by cortical terminals wereapposed by terminals derived from both cortical regions, whichrepresents up to 23% (range, 8.8-23.5) of all PV-positive neuronsin the single sections. In addition, single axons anterogradelylabeled from either M1 or S1 were frequently found to form multipleappositions with individual PV-positive interneurons within afew microns (Fig. 4). They commonly gave rise to two or threeboutons apposed to an individual PV-positive neuron, althoughas many as six were observed (Fig. 4).

Electron microscopic observations

To confirm that the appositions observed in the light microscopic analysis were indeed synapses, PV-positive neurons wereexamined by electron microscopy. Correlated light and electronmicroscopy was performed because the extent and quality of immunohistochemicaland histochemical staining is reduced in material prepared forelectron microscopy. A total of eight PV-positive neurons (twofrom each of the four rats) that were apposed by terminals fromboth M1 and S1 were selected at the light microscopic level forstudy in the electronmicroscope.

In the electron microscope the cell bodies and dendrites of the labeled PV-positive structures contained an amorphous, electron-densereaction product similar to that previously reported for VectorSG (Hussain et al., 1996; Hanley and Bolam, 1997). Ultrastructuralfeatures of the PV-immunoreactive structures were consistent withprevious descriptions (Kita et al., 1990; Lapper et al., 1992;Bennett and Bolam, 1994). They possessed a relatively large volumeof cytoplasm that was rich in organelles such as mitochondria,ribosomes, and Golgi apparatus (Figs. 5B,C,E,F, 6B,C,E,F). Thenuclear membrane possessed indentations (Figs. 5E, 6E), and intranuclearinclusions were often observed (Fig. 5E). Anterogradely labeledaxon terminals were identified by the presence of reaction productas well as by their position in relation to landmarks such asblood vessels, unstained neurons, and glial cells (Figs. 5B,C,E,F,6B,C,E,F). Axons and terminals that were visualized using nDABwere more intensely stained than DAB-labeled structures (compareFigs. 5C,F, 6C,F). Consistent with previous studies (Kemp andPowell, 1971a; Somogyi et al., 1981a; Dubé et al., 1988; Smithet al., 1994; Hersch et al., 1995) the anterogradely labeled corticostriatalboutons were packed with round vesicles and usually containedone or more mitochondria (Figs. 5C,F, 6C,F). They formed asymmetricsynapses with dendritic spines and with dendritic shafts. Theterminals were variable in size, and some of the larger boutonswere similar in morphology to the boutons of the "discrete" corticostriatalprojection from the barrel cortex (Wright et al., 1999). The correlatedlight and electron microscopy revealed that they also formed asymmetricsynapses on the cell body and proximal dendrites of PV-positiveinterneurons (Figs. 5, 6). Of the eight cells studied, five ofthem (from three rats) were found to receive convergent synapticinput from both the M1 and S1 cortices (Figs. 5, 6). In one ofthe neurons that received the convergent input, three synapsesfrom the motor cortex arose from a singleaxon.

Of the three neurons that were examined by correlated light and electron microscopy and failed to reveal convergent inputfrom the cortex, two were abandoned because of poor ultrastructuralpreservation. In only one case was a labeled bouton identifiedat the light microscopic level found not to make contact withthe PV-positive neuron; the bouton, anterogradely labeled fromS1, made synaptic contact with an adjacent, unstained dendriticspine (data notshown).

In addition to the labeled boutons identified at both the light and electron microscopic levels, additional labeled boutonswere observed in contact with the PV-positive neurons. These boutons(n = 6) had the morphology of corticostriatal boutons and formedasymmetric synapses, and they were usually found below the PV-labeledcell bodies. In addition to these, many unlabelled boutons formedasymmetric synaptic contacts with PV-immunolabeled cell bodiesanddendrites.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Synaptic convergence in the striatum

The primary objective of the present study was to determine whether synaptic convergence of somatosensory and motor corticostriatalprojections occurs at the level of single interneurons in theareas of overlap of these projections. The main finding is thatsomatosensory and motor corticostriatal afferents do indeed formconvergent synapses with individual PV-positive striatal interneurons,indicating that one aspect of sensory-motor integration performedby the basal ganglia occurs at the level of single cells in thestriatum.

The major targets of corticostriatal axons are the dendritic spines of spiny projection neurons and the dendritic shafts ofPV-positive, GABAergic interneurons (Kemp and Powell, 1971a; Somogyiet al., 1981a; Lapper et al., 1992; Bennett and Bolam, 1994).Our analysis was confined to the latter class of neuron and lightmicroscopy revealed that the dendrites and perikarya of PV-positive,GABAergic interneurons were apposed by terminals derived fromboth the primary motor and somatosensory cortices. The analysisof sections at the level of the densest overlap of the two projectionsrevealed that this was a common phenomenon, because up to a halfof PV-positive neurons that were apposed by terminals derivedfrom the cortex had convergent appositions from both regions ofthe cortex. This value is likely to be an underestimate of thetrue incidence of convergence as numerous isolated PV-positivedendrites were apposed by both sets of terminals and at leastsome of these may have arisen from the PV-positive perikarya andproximal dendrites that were not found to be apposed by both setsof cortical terminals. Furthermore, the entire projection fromthe areas of cortex that received the deposits of the tracersis unlikely to have been labeled, nor is the entire dendriticarbor of a PV-positive neuron likely to beimmunolabeled.

To confirm that the convergent appositions that we observed at the light microscopic level were indeed synaptic connections,analysis was performed at the electron microscopic level. Becauseof the lower frequency of convergent appositions observed at thelight microscopic level in material prepared for electron microscopyand because of the difficulty in distinguishing DAB and nickelDAB reaction products at the electron microscopic level, we performedthe analysis by correlated light and electron microscopy. Thisanalysis revealed that indeed, the PV-positive interneurons receiveconvergent synaptic input from both the primary motor and sensorycortices. The cortical terminals formed asymmetric synapses withthe dendritic shafts and perikarya of the PV-positive neurons.Of the six neurons analyzed in detail at the electron microscopiclevel, in only one case did the apposing bouton identified atthe light microscopic level not form synaptic contact with thePV-positive neuron. The identification of synaptic convergencein five of the six cases implies that the light microscopic analysisclosely reflects the incidence of synaptic connections and thatthe phenomenon of convergence of motor and somatosensory inputsto PV-positive, GABAergic interneurons is a commonevent.

These findings imply that PV-positive, GABAergic interneurons play a role in sensorimotor integration in the striatum. Althoughtheir precise role remains undetermined, it is likely that thesensory and motor information integrated by PV-positive, GABAergicinterneurons is transmitted to spiny projection neurons in sucha form as to control the output of a selected group of spiny neuronsby shunting cortical excitation and/or by synchronization of theiractivity (Plenz and Kitai, 1998; Koos and Tepper, 1999).

Because spiny projection neurons are the major target of the corticostriatal projection, there are additional possibilitiesfor the synaptic convergence of corticostriatal afferents. Itremains to be established whether the input from the two regionsof the cortex is targeted at distinct populations of spiny neuronsprojecting to the same or different regions or whether they convergeon the same spiny projection neurons. Similarly, synaptic convergencemay occur on other classes ofinterneurons.

Pattern of cortical innervation of PV-positive interneurons

An additional observation that was made in the present study has a bearing on the principles of organization of the corticostriatalprojections. At the light microscopic level, single axons fromM1 or S1 were often seen to form multiple appositions (up to sixwere observed) within a small distance on a single PV-positiveinterneuron. In one case it was confirmed by electron microscopythat the closely spaced multiple appositions do form synapticcontacts. It has been calculated that a single cortical axon willform ~40 synapses within the volume of striatum occupied by asingle spiny neuron. Because that same volume of striatum willcontain 2845 spiny neurons (each of which receive ~5000 corticalsynapses), the probability of an individual cortical axon contactinga spiny neuron is low (Kincaid et al., 1998). The same volumeof striatum will contain ~18 PV-positive neurons, based on theestimate of 16,875 PV-positive neurons (Luk and Sadikot, 2001)and 2.72 million spiny neurons (Oorschot, 1996) in the striatumand assuming an even distribution (which may in fact not be thecase: see Cowan et al., 1990; Kita et al., 1990). If corticalaxons innervate striatal neurons in a nonselective way, then theprobability of a cortical axon contacting a PV-positive neuronis very low, and the probability of it forming more than one contactis even lower (Kincaid et al., 1998; Zheng and Wilson, 2002).However, we commonly observed multiple appositions in contactwith an individual PV-positive neuron and thus, cortical axonsmust, in some way, show selectivity for the PV-positive neurons.Given that the same volume of striatum contains 381,180 corticalaxons (Kincaid et al., 1998; Zheng and Wilson, 2002), those axonsthat form multiple contacts with the 18 PV-positive neurons must,therefore, be a subpopulation. It remains to be established whichof the several classes of cortical neurons that innervate thestriatum provides this selective innervation (Gerfen and Wilson,1996; Kincaid and Wilson, 1996).

From the light microscopic analysis it was apparent that an individual cortical axon that was apposed to a PV-positive structurealso gave rise to boutons not apposed to PV-positive structures.This implies that individual cortical axons contact both PV-positiveinterneurons and spiny neurons and/or other classes of interneurons.An intriguing possibility is that the PV-positive, GABAergic interneuronsand the population of spiny neurons contacted by the same corticalaxons are bound together by the axon collaterals of the interneuron,thereby forming some type of modular arrangement. It should benoted, however, that the influence of GABAergic interneurons islikely to extend beyond their axonal field because they are interconnectedby dendritic gap junctions (Kita et al., 1990; Kita, 1993; Koosand Tepper, 1999).

Together with differences in intrinsic membrane properties (Kawaguchi, 1993; Plenz and Kitai, 1998; Koos and Tepper, 1999),the finding that PV-positive interneurons receive multiple contactsfrom a single axon also suggests that they may be activated bya weaker and/or less synchronized cortical input than is requiredto activate a striatal projection neuron (Wilson, 1995; Sternet al., 1997; Charpier et al., 1999). Thus, GABAergic interneuronsare likely to be more responsive to cortical inputs than spinyneurons. This suggestion is consistent with the studies of Parthasarathyand Graybiel (1997), who showed that weak cortical stimulationwas unable to activate a large number of projection neurons butwas able to induce immediate early gene expression in PV-positiveinterneurons. It may be that although many corticostriatal neuronsneed to fire synchronously to evoke activity in spiny projectionneurons (Wilson, 1995; Stern et al., 1997; Charpier et al., 1999),input from fewer corticostriatal neurons, albeit from differentcortical regions, is needed to activate PV-positive interneurons.Thus, PV interneurons may shunt coincident cortical activity insuboptimally excited striatal spiny cells (Parthasarathy and Graybiel,1997; Plenz and Kitai, 1998; Koos and Tepper, 1999). Only whencortical input to the spiny neurons is sufficiently large willthe shunting be overcome and the selected population of spinyneurons be allowed to reach firingthreshold.

The overlapping corticostriatal projections from primary motor and somatosensory cortices do not remain segregated at thesingle cell level of the striatum, but rather, give rise to convergentsynapses on individual PV-positive GABAergic interneurons. Thus,one mechanism by which the basal ganglia integrates sensory andmotor information is through convergent cortical inputs to GABAergicinterneurons which, in turn, transmit this integrated informationto spiny projection neurons to shunt excitatory inputs to thesecells or synchronizes theiractivity.

  FOOTNOTES

Received May 20, 2002; revised June 21, 2002; accepted June 25, 2002.

This work was supported by the Medical Research Council (UK) and the European Community (BIOMED 2 Project: BMH4-CT-97-2215).We thank Caroline Francis and Paul Jays for technical support.We also thank Justin Boyes, Peter Magill, and Ahmed Sadek fortheir comments on thismanuscript.

Correspondence should be addressed to J. P. Bolam, Medical Research Council Anatomical Neuropharmacology Unit, Departmentof Pharmacology, Mansfield Road, Oxford, OX1 3TH, UK. E-mail:paul.bolam{at}pharm.ox.ac.uk.

S. Ramanathan's present address: Department of Preclinical Veterinary Sciences, Royal (Dick) School of Veterinary Sciences,University of Edinburgh, Edinburgh, EH9 1QH,UK.

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