Connectivity and Convergence of Single Corticostriatal Axons

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The Journal of Neuroscience, June 15, 1998, 18(12):4722-4731

Connectivity and Convergence of Single Corticostriatal Axons
Anthony E. Kincaid, Tong Zheng, and Charles J. Wilson
Department of Anatomy and Neurobiology, University of Tennessee College of Medicine, Memphis, Tennessee 38163

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The distribution of synapses formed by corticostriatal neurons was measured to determine the average connectivity and degreeof convergence of these neurons and to search for spatial inhomogeneities.Two kinds of axonal fields, focal and extended, and two striataltissue compartments, the patch (striosome) and matrix, were analyzedseparately. Electron microscopic examination revealed that bothkinds of corticostriatal axons made synapses at varicosities thatcould be identified in the light microscope, and each varicositymade a single synapse. Thus, the distribution of varicositieswas a good estimate of the spatial distribution of synapses. Thedistance between axonal varicosities was measured to determinethe density of synaptic connections formed by one axon withinthe volume occupied by a striatal neuron. Intersynaptic distanceswere distributed exponentially, except that synapses were rarelylocated <4 µm apart. The mean distance between synapses was ~10µm, so axons made a maximum of 40 synapses within the dendriticvolume of a spiny neuron. There are ~2840 spiny neurons locatedwithin the volume of the dendrites of one spiny cell (Oorschot,1996), so each axon must contact $<=$ 1.4% of all cells in its axonalarborization. Within the same volume there are ~30.5 million asymmetricsynapses (Ingham et al., 1996), approximately half of which arecortical in origin. Thus, ~380,000 cortical axons innervate thevolume of the dendritic tree of one spiny cell. Striatal neuronswith totally overlapping dendritic volumes have few presynapticcortical axons in common, and cortical cells with overlappingaxons have few striatal target neurons in common. These resultsexplain the absence of redundancy in the responses of neuronslocated near each other in the striatum.

Key words: cerebral cortex; neostriatum; synapse; axonal arborization; neuronal connectivity; convergence; divergence

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Since the pioneering work of Webster (1961), cortical afferents to the neostriatum have been known to maintain an orderlyspatial map of the cortex within the three dimensional structureof the neostriatum. Although early studies of the nature of thecorticostriatal projection suggested that it was a continuousone in which near neighbors in the cortex are connected to nearneighbors in the neostriatum (Kemp and Powell, 1970), more recentfindings have shown it to be essentially discontinuous (Selemonand Goldman-Rakic, 1985; Malach and Graybiel, 1986). The discontinuitiesare most clearly shown in axonal tracing studies from physiologicallycharacterized cortical regions performed by Flaherty and Graybiel(1991, 1993a) and Parthasarathy et al. (1992). These experimentsshow that individual locations in the cortex give rise to multipleseparate foci of innervation in the neostriatum and that axonsfrom functionally related cortical regions (e.g., the finger areaof primary motor and somatosensory cortex) share common focalinnervation zones. Subsequent studies of the arborization patternsof single corticostriatal cells have shown that many of thesemake multiple focal axonal arborizations in the neostriatum, correspondingin both size and number to the foci seen in the population axonaltracing studies (Cowan and Wilson, 1994; Levesque et al., 1996).Thus, this arrangement probably does not represent a separationof projections from adjacent cortical neurons but, rather, a replicationof the entire output of a single cortical region to several differentplaces in the neostriatum. Moreover, Flaherty and Graybiel (1994)have shown that the output from these separate neostriatal representationsof a single cortical region may reconverge in the globus pallidus.It has been suggested that the discontinuous nature of the corticostriatalmapping is suited for a discrete combinatorial function in whichcortical output is separated at the striatal level to allow forthe independent interactions of cortical inputs within each focus(Brown, 1992; Graybiel et al., 1994).

According to this idea, the functional unit of computation in the neostriatum is the set of neurons located in a 200- to 500-µm-diametercluster (striosome or matrisome) receiving a common set of convergingcorticostriatal inputs. The internal organization of such clustershas not yet been determined. The most simple interpretation isthat all the neostriatal cells in a single cluster are interchangeable,all of which redundantly represent a particular combination ofinputs determined by the convergence of inputs that is specificfor that focus. This view is supported by the finding that cellsresponding to movement of single body parts are located in similarclusters (Alexander and DeLong, 1985a,b). Alternatively, theremay be a spatial fine structure in which some important functionalparameter (e.g., direction of motion) is mapped spatially withinthe cluster. Finally, each cluster may contain a mixture of functionallyrelated but unique input combinations in no particular spatialorder.

These different functional models for the internal details of the striatal cell clusters predict different structural arrangementsfor axons arborizing within the clusters. For example, the interchangeabilityof neostriatal cells in the first interpretation could only bestrictly true if every cortical axon innervating the focus madesynaptic connections with all the neostriatal neurons within thefocus. The second and third interpretations (a microtopographywithin the arborizations or a mixture of functionally unique combinations)would both require the opposite. For these, individual axons shouldnot connect with a large proportion of cells within the focalarborization. The difference between these two latter interpretationsdepends on the presence or absence of a spatial inhomogeneityof synaptic connectivity within the arborizations of single axons.In the experiments described here, the spacing of synapses alongindividual corticostriatal axons was used to probe for spatialinhomogeneities within the axonal arborizations to determine theaverage number of synapses formed within a dendritic tree of asingle striatal neuron and the average amount of input sharingthat may occur among nearby neostriatal neurons.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Axonal arborizations in the neostriatum of rats were stained by intracellular injection of biocytin during intracellular recordingof identified corticostriatal neurons of the medial agranularfield or by small extracellular injection of biotinylated dextranamine (BDA) in the cingulate, medial agranular cortex, or lateralagranular cortex. When extracellular injections were used, tissuesections were counterstained with calbindin to reveal the calbindin-poorpatch (striosome) and calbindin-rich matrix compartments of theneostriatum, and sections were prepared so that they could beused for both light and electron microscopy. Intracellularly stainedaxons were used for light microscopy only. Estimates of synapticdensity were obtained by measuring the spacing between adjacentboutons along individual stained axons. To determine whether theseboutons actually represent synapses and whether synapses occurspecifically at boutons, the axonal diameters at synaptic andnonsynaptic regions of corticostriatal axons were compared usingelectron microscopy.

BDA injections. For extracellular tracing, injections of BDA (Molecular Probes, Eugene, OR) were made into the cingulate,medial agranular cortex, or lateral agranular cortex of adultSprague Dawley rats. Animals were anesthetized intraperitoneallywith a mixture of 100 mg/kg ketamine and 20 mg/kg xylazine. Aglass micropipette with a tip diameter of 20-40 µm was filledwith a solution of 5% BDA in isotonic saline buffered with 0.01M phosphate buffer, pH 7.4, and placed in the cerebral cortex1.0-2.0 mm from the surface. The details of injection sites andthe macroscopic pattern of axonal arborizations from these injectionshave been described previously (Kincaid and Wilson, 1996). BDAwas ejected using 5 µA current pulses lasting 7 sec and presentedevery 17 sec for 10-30 min. After a recovery time of 7-12 d toallow for transport of BDA throughout the corticostriatal fibers,the animals were again anesthetized and perfused with 150 ml ofisotonic buffered saline followed by 400 ml of a solution of 4%formaldehyde in 0.1 M phosphate buffer. The brains were fixedovernight in the fixative solution and cut in the coronal planeon a vibratome at a thickness of 50 µm. For visualization of BDA,tissue sections were incubated in ABC (1:200; Vector Laboratories,Burlingame, CA) containing 0.2% Triton X-100 for 2 hr, washedin buffered saline, and reacted for 10-20 min in a solution of0.05% diaminobenzidine, 0.003% hydrogen peroxide, and 0.12% nickelchloride in buffered isotonic saline. The sections were washedthoroughly and incubated in mouse anti-calbindin antibody (1:000;Sigma, St. Louis, MO) with 0.2% Triton X-100 overnight at 4°C.They were then washed thoroughly, treated with biotinylated anti-mousesecondary antibody (1:200; Vector) for 2 hr, and treated againas described above, except for the omission of nickel chloride.The reaction time of this step was shortened to yield a light-brownreaction product in the matrix compartment of the striatum.

Intracellular staining. Corticostriatal neurons were identified in the cortex of adult male Long-Evans rats anesthetized withurethane (1.5 gm/kg) supplemented hourly with a combination ofketamine (30 mg/kg) and xylazine (6 mg/kg, i.m.). Neurons projectingto the neostriatum were impaled using micropipettes containing4% biocytin in 1 M potassium acetate and identified by antidromicactivation from the contralateral neostriatum or the ipsilateralcerebral peduncle. Biocytin was ejected by passing 0.5-1.0 nAcurrent pulses, 300 msec in duration, applied every 600 msec for15-45 min. At the end of the experiment, animals were perfusedintracardially with a fixative containing 4% formaldehyde and0.1% glutaraldehyde and treated as described above for animalsgiven extracellular BDA injections. Two of the axons analyzedin the study were originally collected in the course of anotherexperiment, as described by Cowan and Wilson (1994). A third axonwas also analyzed. This cell was selected because it exhibitedthe focal pattern but was verified as arborizing exclusively inthe matrix using calbindin counterstaining. After drying ontoslides, sections prepared for light microscopy shrank 28-44% inthickness, as measured using the focal plane method in the microscope.All measurements were corrected in that dimension using the measureddegree of shrinkage, whereas shrinkage in the other dimensionswas negligible and was not corrected. Tissue prepared for electronmicroscopy (see below) showed no measurable shrinkage in any dimension,and no corrections were made. Measurements of the distances betweenboutons were made using a 100× oil immersion objective (numericalaperture, 1.4), and boutons were plotted in three dimensions usinga computer-aided microscope and a video camera. The three-dimensionaldistances between adjacent boutons were measured automaticallyusing the coordinates for the boutons (without regard to the pathof the axon between boutons).

Transmission and high-voltage electron microscopy for measurement of axonal diameters. Neurons used for high-voltage electronmicroscopy (HVEM) and conventional electron microscopic analysiswere collected as described above, except for the addition of0.1% glutaraldehyde to the fixative and the exclusion of TritonX-100 from all solutions. After processing, the sections werepost-fixed in a solution of 0.25% osmium tetroxide in 0.15 M phosphatebuffer, infiltrated with epoxy resin, and embedded between slidesand coverslips coated with liquid releasing agent (Polysciences,Warrington, PA). Areas selected for electron microscopic studywere removed from their mounts and glued to blocks for resectioningon an ultramicrotome. For HVEM study, thick sections (2-5 µm)were cut using a dry glass knife, collected on uncoated sandwichgrids, and examined at 1000 kV using the high-voltage electronmicroscope at the University of Colorado (Boulder, CO). Methodsfor HVEM preparation have been described in detail elsewhere (Wilson,1994). Ultrathin sections for conventional electron microscopywere cut with a diamond knife and examined at 80 kV on a JEOL200EX microscope. Because the calbindin antiserum did not fullypenetrate the vibratome sections, the selection of tissue frompatch or matrix compartments could be made in the light microscope,but thin sections were collected from regions located deeper withinthe section where the calbindin labeling was not present. Thisprevented any ambiguity between the labeling of corticostriatalaxons and axons of the striatal spiny neurons positive for calbindin.In addition, all axons used for these experiments were positivelyidentified as profiles of corticostriatal axons seen in the lightmicroscopic examination of the same specimen. Diameters of profilesin the electron microscope were measured by digitizing the images,drawing the outlines of their profiles using NIH Image software,and measuring the short and long (perpendicular) diameters throughthe centroid of the profile using that software.

Connectivity calculations. Connectivity calculations were made using the binomial theorem. The approach was similar to thatdescribed by Abeles (1991). To determine the number of axons making0,1, ... k synapses on spiny neurons, the probability of makinga synapse on a particular cell was taken as the reciprocal ofthe number of candidate cells in the volume. Thus, the probabilityof making k synapses with n synapses per axon was given as:

where p is 1/number of candidate cells, and n is the number of synapses per axon. The number of axons in each category wascalculated by multiplying the probability obtained in this wayby the number of candidate axons innervating the volume.

A similar approach was used to determine the probability of shared input to single cells and the probability of two corticalaxons converging on k spiny neurons. To determine the number ofcortical inputs held in common by two spiny cells, the probabilityof a synaptic contact by a given axon was taken as the squareof the quotient of cortical synapses per cell and the number ofcandidate cortical axons. The likelihood of two spiny neuronsreceiving 0,1,2, ... k axons in common was calculated as above,using the probability of a contact on both cells from a singleaxon as p and the number of candidate axons as n. To determinethe number of spiny cells jointly innervated by any pair of corticalaxons, the probability of sharing any one target neuron was calculatedas the square of the probability of either axon innervating thecell (as described above). The likelihood of two axons jointlyinnervating 0,1,2, ... k spiny neurons was calculated as above,using this probability for p and the number of candidate striatalcells in the volume as n.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

As described previously (Wilson, 1987; Cowan and Wilson, 1994), corticostriatal axonal arborizations arose either as collateralsof descending axons in the internal capsule fascicles or as arborizationsof axons that did not join the internal capsule but terminatedwithin the neostriatum. In addition to this difference in axonsof origin, the cells formed one of two different kinds of arborizations.Some corticostriatal axons formed one to four small arborizations,~0.5 mm in diameter, usually separated by >0.5 mm. These arborizations,which will be called focal, often arose from collaterals of descendingaxons. The other form of axonal arborization was a single largeand sparse axonal arborization, usually $>=$ 1 mm in diameter, whichwill be called the extended type (Kincaid and Wilson, 1996). Inall cases, the intrastriatal axons were extremely fine but showedvaricosities that were easily identified in the light microscope.These varicosities were not present along the axonal trajectorythrough the white matter or internal capsule fascicles. Althoughthey were easily identified in the light microscope, they weretoo small to measure accurately using that instrument. This wasevident because their apparent diameter was <1 µm, and the diameterof intervaricose segments appeared to be <0.5 µm. For comparisonwith identified synaptic regions in thin sections, it was desirableto have more accurate images of the diameters of the varicositiesand intervaricose segments as seen in the light microscope (LM).For this purpose, images were taken using HVEM of thick (3-5 µm)sections stained as for light microscopy. Examples showing theappearance of axonal varicosities in the LM and the HVEM are shownin Figure 1. The varicosities varied from 0.2 to 1.0 µm in diameterwhen measured using HVEM, whereas the intervaricose segments were~0.1 µm in diameter. Varicosities were more apparent in the HVEMimages than in the LM. The intervaricose segments appeared tobe of larger diameter in the LM because of filtration by its pointspread function. For the same reason, measurements of varicositydiameter in the LM were also inaccurate, but comparison of theLM and HVEM images of the same axons showed that the locationof the varicosities could reliably be determined. In thin sectionscut from the same animals, biocytin-labeled axons were photographedand measured using conventional electron microscopy. A sampleof 56 axonal profiles with an evident synapse and 95 profileswith no evident synapse was measured. In addition, two axons werereconstructed in serial thin sections through at least one synapticsite, allowing repeated measurements of the same axons at synapticand nonsynaptic regions. The results of this analysis are shownin Figure 1. Together, these data confirm that the axonal varicositiesseen in the LM and HVEM correspond to synaptic sites seen by electronmicroscopy of thin sections. Furthermore, each axonal varicosityexamined formed a single synapse, indicating that bouton countswithin the axonal arborization are a good estimate of the totalnumber of synapses.

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Figure 1. Synapses occur exclusively at varicosities on corticostriatal axons. A, Varicosities as they appear in the light microscope stained by anterograde transport of BDA. The diameters of the intervaricose regions cannot be measured accurately, but the varicosities were as large as 1 µm in diameter. B, High-voltage electron micrograph from a 4-µm-thick section through axons as in A. Intervaricose segments were resolved and measured to be ~0.1 µm in diameter. Varicosities were between 0.2 and 1.0 µm. C, Thin-section conventional electron micrograph through a varicosity on a BDA-labeled corticostriatal axon. A single synapse was formed with an unlabeled dendritic spine. The diameter of the axon at the synaptic site is ~0.5 µm. Scale as in D. D, Thin-section conventional electron micrograph through the intervaricose segment of a labeled corticostriatal axon. As was typical for this part of the axon, there were no vesicles present and no synaptic contact. The diameter of the axon is ~0.1 µm. E, Histogram of the diameters of nonsynaptic vesicle-free profiles of BDA-labeled corticostriatal axons examined in conventional electron micrographs as in C and D. Axonal diameter was measured on the short diameter of each profile. F, Histogram of diameters of vesicle-containing profiles in thin sections measured in E.

The distribution of axonal varicosities along corticostriatal axons is shown in Figure 2. Figure 2, E and F, shows distributionsgenerated by pooling many fragments of axonal arborizations stainedby extracellular injections of BDA. Most corticostriatal projectionsto the patch compartment arise from axons forming focal arborizations.In general, projections to the matrix are more heterogeneous,with both focal and extended arborizations contributing significantly(Kincaid and Wilson, 1996). Because the goal was to compare focaland extended arborizations, samples of the matrix were selectedfrom the portion of the projection containing primarily extendedarborizations. Thus, the matrix measurements are an estimate ofprimarily extended arborizations, and the patch sample is primarilyfocal arborizations. Matrisomal arborizations are not representedin the BDA data but were measured for single axons. As shown inFigure 2, the distribution of axonal spacings did not differ inthe two compartments. The relative contribution of axons of theextended and focal types also differed in the projections fromdifferent cortical regions, with the extended type being mostpronounced for the medial agranular (premotor) field. Table 1compares the intervaricose spacing for the three different corticalfields examined and shows that there were no differences amongcortical fields or between projections to the patch or matrix.In all cases, the distribution was highly asymmetrical, beingskewed to the right, and the tail of the distribution was approximatelyexponential. The distribution was not exponential at short intervaricosedistances, with distances <1-4 µm being much less common thanexpected for an exponential distribution. A similar distributionhas been reported for the spacing of varicosities along axon collateralsof pyramidal neurons in the cortex (Hellwig et al., 1994).

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Figure 2. Distribution of boutons along axonal branches in the patch and matrix and in single axons arborizing in extended and focal patterns. A, Drawing of a focal arborization from a single corticostriatal neuron stained by intracellular injection of biocytin. In the drawing, the arborization was projected onto the sagittal plane. Twenty-two boutons were present in this arborization. B, Drawing of the axon of another corticostriatal neuron arborizing in the extended manner, shown at the same magnification and in the same plane. This axonal arborization contained 935 boutons. C-F, Distribution of distances between nearest neighbor boutons along corticostriatal axons. The straight-line distance between nearest neighbor boutons along axonal branches was measured to make these histograms. Individual axonal branches seldom approached each other (the appearance that they do in the drawings is caused by the projection onto two dimension), so measurements along branches accurately represent absolute nearest-neighbor relationships. For each histogram, an exponential curve has been fit to the tail of the histogram (ignoring the bins preceding the peak of the histogram) and is shown as a solid line. The decay constant for the best-fitting exponential is indicated for each histogram ( $lambda$ s). This would be the mean spacing between boutons if the distribution were truly exponential. The actual mean spacing is also indicated for each histogram ( $X$ ). The difference between these is primarily attributable to the deviation from an exponential distribution near zero. In all cases, there were fewer interbouton segments shorter than 1-4 µm than expected on the basis of the exponential distribution. C, Histogram for the focal axonal arborization shown in A. D, Histogram of interbouton spacing for the extended arborization shown in B. E, Histogram of spacing among 1425 boutons measured from corticostriatal axons arborizing in the matrix compartment (mostly extended type) in sections from BDA injections from four animals. F, Histogram of the patch compartment (mostly focal) calculated from four animals as in E.


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Table 1. Intervaricose distances for BDA-stained corticostriatal axons

To further examine the possibility of differences in synaptic spacing among axons showing different arborization types, thedistributions of intervaricose distances were also measured forthree arborizations of single corticostriatal axons stained byintracellular injection. All three of these neurons arose fromthe medial agranular cortical field. Examples of one focal andone extended type arborization are shown in Figure 2, A and B,and the distributions of intervaricose segments from these areshown in Figure 2, C and D. Although the extended axonal arborizationformed many more varicosities over a much larger volume of theneostriatum, the individual branches of the arborization wereseparated by relatively large distances, and the spacing of varicositiesalong the branches was not distinguishable from that seen in thefocal arborizations. Regardless of axonal type, the number ofsynapses generated by corticostriatal axons within a region comparablewith the volume of the dendritic tree of a spiny neuron is approximatelythe same. Axons forming focal arborizations had more axonal brancheswithin the volume occupied by the dendritic tree of a spiny neuron(~400 µm radius) but still made between 20 and 40 synapses withinthe volume. The individual branches of the extended arborizationswere generally spaced so far apart that only one branch couldcross over the dendrites of any one spiny neuron but could makeup to 40 synapses within that volume. The superimposition of axonsin Figure 2B is attributable to the projection into two dimensions.Most axons contributing synapses within the dendritic volume ofa spiny neuron would make <40, because they would not pass throughthe center of the dendritic tree.

The spacing of synapses along the axons of corticostriatal axons can be combined with a number of previously published observationsto set upper and lower limits on the connectivity of the pathwayand sharing of common inputs by nearby striatal neurons. Mostcorticostriatal synapses (~95%) are formed with the dendriticspines of the spiny projection neurons of the striatum (e.g.,Kemp and Powell, 1971b; Somogyi et al., 1981; Xu et al., 1989).These spines are distributed throughout the dendritic trees ofthe cells, except for a region within ~20 µm of the soma. Thedendrites extend in an approximately spherical manner with a diameterof ~400 µm (Kemp and Powell, 1971a; DiFiglia et al., 1976; Wilsonet al., 1983b; Wilson, 1992). Although many dendritic trees aredistorted from the spherical (Kawaguchi et al., 1990; Walker andGraybiel, 1993), this is still a best estimate of the volume theyoccupy. Thus, the dendritic field of each spiny neuron occupiesa region of ~33,500,000 µm³. Within that volume, in the rat there are an average of 2845neurons (based on the shrinkage-corrected estimate of 84,900 neurons/mm³ by Oorschot, 1996), most of which (~95%) are spiny cells. Thenumber of corticostriatal synapses that will be found in thatvolume can be estimated from the published report of Ingham etal. (1996), who measured the density of asymmetric synapses inthe neostriatum using unbiased sampling in ultrathin sectionsand estimated that there are 0.91 afferent-type (asymmetric) synapsesper cubic micrometer, or ~30,500,000 within the volume occupiedby the dendritic tree of one spiny neuron. Based on their studiesof spine loss after lesions, Kemp and Powell (1971c) concludedthat the corticostriatal and thalamostriatal inputs to spiny neuronswere approximately equal. Although not a direct measurement, thisestimate is consistent with more recent qualitative studies ofthese two pathways (Dubé et al., 1988; Xu et al., 1991; Ragsdaleand Graybiel, 1991; Berendse and Groenewegen, 1990), which togetheraccount for most of the asymmetric synapses. It is also in agreementwith neurophysiological studies showing approximately equal-sizedmonosynaptic responses of striatal neurons to stimulation of axonalpathways from the cortex and thalamus (Wilson et al., 1983a; Wilson,1986). Assuming the cortical input as the origin of 50% of allasymmetric synapses in the striatum, there are ~15,250,000 corticostriatalsynapses within the volume occupied by one spiny neuron dendriticfield in the rat. Estimates of the number of asymmetric synapsesper spiny neuron have been calculated using spine density (Wilsonet al., 1983b). Integration of the spine density distributionalong individual dendrites published by Wilson et al. (1983b)yields an estimate of between 250 and 500 spines per spiny dendriticbranch. Each neuron has 25-30 such spiny dendrites, yielding valuesbetween ~6250 and 15,000 spines per neuron, depending on the numberof dendrites on each cell. As each dendritic spine receives oneasymmetric synapse (Wilson et al., 1983b), this yields the samenumber of asymmetric synapses per cell. Using an independent approach,the stereological measurements of Ingham et al. (1996) and Oorschot(1996) together yield an average asymmetric synapse count of 10,719(9.1 × 10⁸ synapses/mm per 84,900 cells/mm) per striatal neuron (all typescombined). This average number, which is in good agreement withthat obtained by spine counts, will be used for subsequent calculations.The axonal measurements reported here indicate that individualcorticostriatal axonal arborizations of both the extended andfocal types usually have only one branch passing through the volumeoccupied by the dendritic tree of any one striatal projectionneuron, and that on average a maximum of 40 asymmetrical synapseswill be formed by the axon in that volume. The exceptions to thiswere axons of the focal arborizations, which formed <40 synapsesin a volume approximately the size of a spiny cell dendritic tree.In both cases, of the 15,250,000 corticostriatal synapses present, $<=$ 40 (0.00027%) could be formed by a single axon. Conversely, ~381,180different corticostriatal axons would be required to arborizein that volume to achieve the known density of corticostriatalsynapses. These calculations are independent of the degree towhich cortical axons make repeated contacts on single striatalcells. They are summarized in Table 2.


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Table 2. Measurements of corticostriatal connectivity within the volume of one projection neuron's dendritic tree

It is not known whether individual corticostriatal axons make multiple synaptic contacts on single spiny neurons. Becausethe axons do not make boutons in clusters, and the dendritic fieldsof the striatal neurons radiate throughout their volume, thiscannot be determined from the data at hand. But even if they doso in the most extreme form, one cortical axon can represent onlya tiny fraction of the total cortical innervation of any spinyneuron. If synapses are made promiscuously within the volume ofthe dendritic field of one cell, then each axon may contact asmany as 40 (1.4%) of the 2845 cells of all types whose somataare located in that volume. The chances of any neuron receivingmore than one input from the same axon would be low, so one axoncould only contribute one synaptic contact (0.009%) of the 10,719asymmetrical synapses formed on the average per neuron. Two spinyprojection cells located so close to each other that their dendriticfields totally overlapped would independently sample ~5360 corticalinputs from the 381,180 in that volume and so would have only~75 of their cortical afferent axons in common. Because the axonalarborizations of corticostriatal neurons are usually larger thanthe dendritic fields of spiny neurons, cells located farther apartbut still within the region of overlap of axonal fields wouldhave approximately the same (actually slightly higher) chanceof sharing inputs as those with overlapping dendritic fields.

In the opposite extreme case in which each cortical axon makes all of its synapses on a single postsynaptic neuron, the numberof corticostriatal neurons innervating a single striatal cellwould be 134 instead of 5360, so an individual corticostriatalaxon would account for as much as 0.75% of the cortical inputof a single striatal neuron (0.37% of total asymmetric synapses).However, in that case, nearby striatal projection neurons withoverlapping dendritic trees would never share common inputs. Becauseindividual axons of the focal type project to more than one clusterand extended axonal fields extend across the dendritic trees ofmany cells, striatal cells that separated from each so that theirdendritic fields did not overlap would be much more likely toshare a common input than would nearby cells (although still notlikely in an absolute sense).

A similar calculation can be made for the sharing of target neurons in the striatum by axons arborizing in the same space.If two cortical neurons arborizing in exactly the same space makesynapses with spiny neurons at random in their terminal fields,they will each contact 40 (1.4%) cells of the 2845 in the volume.The chance that both axons converge onto one spiny neuron is 2× 10⁴, and on average there will not be even one neuron within thatvolume that receives synapses from both cortical axons. The statisticsof connectivity for both the nonselective and the totally selectivecases are shown in Table 3.


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Table 3. Corticostriatal statistics assuming four different examples of connectivity rules

A number of intermediate cases can be hypothesized in which single axons are neither completely nonselective nor do they seekout single postsynaptic targets. For example, spiny neurons mayreceive different cortical inputs depending on whether they participatein the direct or indirect pathway. Such a division of the spinyneurons into two populations would not make a significant differencein the results. The key feature for this kind of mechanism isthe ratio of cortical axons to the number of cortical synapsesper spiny neuron. With only two groups of axons, there would stillbe an enormous excess of cortical axons innervating the volumein comparison with the number of corticostriatal synapses on eachcell. Thus, single spiny neurons would still share only a tinyproportion of their input and would receive only a single inputfrom each of the cortical neurons innervating them. To producea substantially higher mean connectivity, the population of axonsthat are candidates for innervating any particular postsynapticcell would have to be reduced so that it is close to the numberof cortical synapses on each spiny neuron. If each axon belongedto a group that had a predisposed affinity to contact only a smallsubset of spiny neurons, this could be achieved. To ensure thateach axon made an average of one synapse on all the candidateneurons in its affinity group, the axons and striatal neuronswould have to be divided into 71 such groups (381,180/5359). Sharingamong affinity groups would be nearly total, and there would beno sharing at all across groups. To average four synapses percandidate striatal neuron, the striatal spiny cells and the innervatingaxons would have to be divided into 284 affinity groups. The resultsfor this arrangement is shown in Table 3 (affinity groups). Thevalue of 4 used in this calculation was chosen arbitrarily toillustrate the concept. There is currently no evidence to suggestany value for the number of contacts on each striatal projectioncell per cortical axon. In a second method for obtaining highermean connectivity, cortical axons could make their initial synapsesin a nonselective manner but once establishing one contact witha spiny neuron establish a strong selectivity for that cell resultingin a mean of more than one synapse per axon. This could arisefrom the action of a growth rule that encourages multiple synapses,such as one based on correlated firing in the presynaptic andpostsynaptic cells. The results from this model are also shownin Table 3 (growth rule), again arbitrarily choosing four synapsesper axon per cell. Table 3 shows that these two patterns producedramatically different results. In the growth rule case, sharingis effectively reduced, because the number of spiny neurons contactedby each axon is reduced from 40 to 10 without any change in thenumber of candidate neurons or axons in the volume. In the affinitygroup case, the axons and cells are divided into 284 differentsubclasses, reducing the number of axons per group to one-fourthof postsynaptic sites per neuron. Each axon innervates nearlyevery spiny neuron in its affinity group, so all the cells inthe affinity group have identical input. The total number of uniquecombinations of inputs represented in the volume is reduced from2840 to 284, and each spiny neuron has exactly the same inputsignal as the nine other cells in its affinity group. Becauseconnectivity is measured across all cells in the volume, the averageconnectivity is approximately 1/284.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Patches (striosomes)

The available information on the convergence of corticostriatal inputs in the striosomal, focal matrix (matrisomal), and extendedmatrix patterns are summarized in Figure 3. In the focal arborizationsof the patches, axonal fields are approximately the same sizeas dendritic trees of spiny cells, and both the axons and thespiny cell dendrites observe the patch boundaries (Penny et al.,1988; Kawaguchi et al., 1989, 1990). As a result, all axons thatarborize in a given patch in rats share a common volume of innervation,and all the dendrites of the cells in the patch at that levelare equally able to be contacted by all the axons. Calculationsof innervation density and connectivity in the patch compartmentare the most simple. Axons fill the patch cross section and makesynapses at equal density everywhere in the arborization, so nospatial gradients of innervation can occur within the volume.The synaptic density generated by one axon is low so there aremany axons, and each one contacts only a small subset (on average, $<=$ 40) of the cells in the volume. Regardless of the degree to whichaxons make repeated contacts on the same spiny cell, the influenceof any one axon on any cell is low, and sharing of inputs is low.If selectivity is higher, sharing of inputs approaches zero. Cellsshare ~75 or fewer input axons in common unless there are affinitygroups on the order of $>=$ 75, as in Table 3 (affinity groups).

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Figure 3. Three different corticostriatal convergence patterns. A, In the patches (striosomes) and perhaps in the matrix focal arborizations (matrisomes), focal corticostriatal axonal fields and spiny neuron dendrites obey the patch boundaries and are approximately the same size as the patch cross-section. In this arrangement, all connectivity is discontinuous, and every cell in the patch has access to all the axons arborizing there. The number of possible synaptic connections on one spiny neuron is merely the number of synapses made in the patch, and there is a direct trade-off between that number and the degree of input sharing in the patch. B, The extended axonal fields of some corticostriatal neurons take a straight course through their large arborizations, with branches separated so that a single neuron is crossed by only one branch. The number of possible synaptic contacts is determined by the interval between synapses along the axon and the diameter of the dendritic tree of the spiny cell. C, Unlike the situation in the striosomes, the focal axonal arborizations of corticostriatal cells in the matrix may not be totally overlapping, and spiny cells may not observe boundaries of matrisomes. In this hypothetical case, a continuous topography is possible.

Focal arborizations in the matrix (matrisomes)

In the focal arborizations in the matrix (matrisomes), we do not know yet whether spiny dendrites obey the boundaries observedby axonal arborizations. Distortions of spiny neuron dendriticfields within the matrix in ways resembling those seen in patcheshave been observed (Kawaguchi et al., 1990; Walker and Graybiel,1993). It is possible that the matrisomes are just as well definedas the patch compartment, but the cytochemical tools for demonstratingtheir boundaries have not yet been discovered. If so, the matrisomesobey exactly the same convergence rules as striosomes. However,it is not certain that the axons that arborize in the focal arborizationsin the matrix are doing so to obey the boundaries of a tissuecompartment or whether they are simply making small arborizations.In the absence of an independent cytochemical marker for thesematrisomes, it is not possible to compare axonal arborizationswith compartmental boundaries, as can be done for the striosomes.Confidence in the reality of matrisomes as tissue compartmentsis undermined by reports of incomplete overlap of projectionsto matrisomes (Flaherty and Graybiel, 1993a). That is, when focalprojections from physiologically characterized cortical regionswere compared, there were occasionally areas of incomplete overlapin the projections of different cortical areas representing thesame body part. This raises the possibility that corticostriatalaxons make focal arborizations in the matrix that overlap moreor less according to a functionally organized topography. Forpurposes of convergence of inputs, this would be the oppositesituation to that of the striosomes. Striatal spiny neurons wouldsend their dendrites into different axonal arborizations accordingto proximity, and there would result a continuous microtopographyin the matrix, with each point of the striatum representing aunique combination of cortical inputs. Even if this is the case(Fig. 3C, Continuous Focal Arborizations: Matrisome?), the lowamount of sharing and the low connectivity with single axons ensuresthat nearby cells will get different inputs, and the combinationof inputs to each striatal cell, even those with totally overlappingdendritic fields, would be unique.

Extended matrix arborizations

The extended arborizations are not usually described in population-labeling studies of the corticostriatal pathway. In thosestudies, they contribute to a generalized background of labelingaround the foci, so their contribution does not stand out well.These axons have been shown to cross patch and matrix boundaries,making synapses in both compartments (Kincaid and Wilson, 1996).Their wide-ranging arborizations give the superficial appearanceof making synapses at a lower density than the focal arborizations,but it is not so. They make many more synapses and make arborizationsas rich as the focal ones but over much larger areas. So far,these have only been seen arising from axons that do not haveaxons descending beyond the neostriatum. Because of the largearborization sizes of these cells, they are unlikely to produceany fine spatial patterning of inputs on the spatial scale ofthe matrisome or smaller. Because the density of the individualbranches of these neurons is low, few spiny cells could be crossedby more than one branch, and so the important issue for thesearborizations is simply the spacing of synapses along the axons.The results of the present study show that, like the focal arborizations,these axons make $<=$ 40 synapses on average while crossing the dendriticfield of a spiny neuron. As in the case of the focal arborizations,the small number of inputs formed within the dendritic tree ofa single cell and the high density of spiny neurons ensures thateach spiny neuron will receive inputs from a large number of suchaxons and that cells with overlapping dendritic trees will notshare many input axons. For this kind of axon, as for the others,two spiny neurons with nonoverlapping dendritic fields are morelikely to share common inputs than cells located near each other.This occurs because an axon having made a synaptic input on oneof two cells with overlapping dendritic trees has thereby reducedby 1 of 40 its chance of contacting another cell in the same location.

Uniqueness of connectivity of striatal neurons

These results offer an explanation for a variety of physiological findings on the functional properties of striatal neurons.Although striatal neurons responding to movement of particularbody parts are found near each other (Alexander and DeLong, 1985b),there is a wide variability of the finer functional propertiesof the cells within a body part (Alexander et al., 1992, theirDiscussion). Striatal neurons responding to movement of a particularbody part are found in clusters ~0.2-0.5 mm in diameter (Alexanderand DeLong, 1985b). These clusters of neurons associated withmovements of single body parts probably correspond to microexcitablezones in which stimulation can evoke movement of a single bodypart (Alexander and DeLong, 1985a) and also to the focal regionsof labeling seen after injections of axonal tracers into physiologicallycharacterized cortical body part representations (Flaherty andGraybiel, 1991). The excitability of clusters to microstimulationprobably arises from antidromic activation of corticofugal neuronsand the recurrent excitation of the motor cortex through axoncollaterals of the corticostriatal cells. However, within thispattern of discontinuous corticostriatal connections, studiesinvolving simultaneous recording of striatal neurons have shownthat nearby cells generally do not show correlations of firingthat would be expected if they all received contacts from thesame axons from the cortex or elsewhere (Jaeger et al., 1995).Likewise, although responding to the same body part, the neuronsin these clusters show an enormous variability in their responsivenessto various other parameters of the task, and this variabilityis not related in any obvious way to their location within thecluster (Hikosaka et al., 1989; Alexander and Crutcher, 1990;Alexander et al., 1992). In light of the anatomical arrangementof corticostriatal connections demonstrated here, these resultsare easily understood as a result of the low level of redundancywithin the corticostriatal projections. Because neurons withinindividual clusters receive their input systematically from certaincortical regions, they respond in the overall pattern typicalof those cortical regions. However, because of the low degreeof input sharing by nearby neurons, each striatal neuron receivesa unique set of inputs from the population of cortical cells.This absence of redundancy among neostriatal neurons is guaranteedas long as each cortical neuron transmits a unique signal, a resultthat is assured by the connectivity within the cerebral cortex(Markram, 1997).

It should be noted that despite the uniqueness of innervation of each neostriatal neuron, the striatum does not encode anexhaustive set of all combinations of cortical inputs. On thecontrary, only a tiny proportion of all combinations of inputsto a single cluster of neostriatal neurons is represented in itsoutput. As calculated above, each volume of striatum equal tothat occupied by a spiny cell dendritic field is innervated by~380,000 corticostriatal axons. Of the possible ~10⁹⁰⁰⁰ combinations when taken 5300 at a time, only ~2800 are expressedby the same number of cells in the volume. Regardless of whetheraxons of cortical cells specifically seek individual target neuronsin the striatum, use an activity-based growth rule for establishingsynaptic contacts, or make synapses at random among availablespiny neurons in the striatum, the low density of synaptic contactsmade by individual cortical axons reported here applies strongconstraints on the interpretation of topography in this projection.Cortical neurons projecting to the same region of the striatumdo not share a common set of postsynaptic cells by virtue of havingoverlapping axonal arborizations, and nearby striatal neuronsprobably do not share more than ~1% of cortical afferent neurons.Thus, the spiny neurons certainly do not fully encode all combinationsof cortical afferents available to them, even when taking intoaccount the dimensional reduction imposed by the topographic natureof the projection. The variation of functional properties of spinyneurons observed within the topography probably reflects cellto cell variation in which the choice of combinations of afferentsare encoded. The absence of fine spatial gradients in these propertiessuggests that at that level, nontopographical factors dominatethe organization of the corticostriatal pathway.

  FOOTNOTES

Received Jan. 20, 1998; revised March 20, 1998; accepted April 7, 1998.

This work was supported by National Institutes of Health, National Institutes of Neurological Diseases and Stroke Grant NS20473.HVEM images were obtained from the High Voltage Electron Microscopyfacility at the University of Colorado at Boulder, which is supportedby National Institutes of Health Grant RR00592.
Correspondence should be addressed to Charles J. Wilson, Department of Anatomy and Neurobiology, University of Tennessee,Memphis, 855 Monroe Avenue, Memphis, TN 38163.

Dr. Kincaid's present address: Department of Physical Therapy, Creighton University, Omaha, NE 68178.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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