Subcortical Input to the Smooth and Saccadic Eye Movement Subregions of the Frontal Eye Field in Cebus Monkey

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Volume 17, Number 23, Issue of December 1, 1997

Subcortical Input to the Smooth and Saccadic Eye Movement Subregions of the Frontal Eye Field in Cebus Monkey

Jun-ru Tian¹ and James C. Lynch¹^,²^,³
Departments of ¹ Anatomy, ² Ophthalmology, and ³ Neurology, University of Mississippi Medical Center, Jackson, Mississippi 39216-4505

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have recently identified two functional subregions in the frontal eye field (FEF) of the Cebus monkey, a smooth eye movementsubregion (FEFsem) and a saccadic subregion (FEFsac). The thalamicinput to these two subregions was studied and quantified to gainmore information about the influence of the cerebellum and basalganglia on the oculomotor control mechanisms of the cerebral cortex.A recent study using transneuronal transport of virus demonstratedthat there are neurons in the basal ganglia and cerebellum thatproject to the FEFsac with only a single intervening synapse (Lynchet al., 1994). In the present study, we concentrated on the thalamicinput to the FEFsem to define possible basal ganglia-thalamus-cortexand cerebellum-thalamus-cortex channels of information flow tothe FEFsem. We localized the functional subregions using low thresholdmicrostimulation, and retrogradely transported fluorescent tracerswere then placed into the FEFsem and FEFsac.
The neurons that project to the FEFsem are distributed in (1) the rostral portion of the ventral lateral nucleus, pars caudalis,(2) the caudal portion of the ventral lateral nucleus, pars caudalis,(3) the mediodorsal nucleus, (4) the ventral anterior nucleus,pars parvocellularis, and (5) the ventral anterior nucleus, parsmagnocellularis. In contrast, the large majority of neurons thatproject to the FEFsac are located in the paralaminar region ofthe mediodorsal nucleus. The FEFsac and FEFsem thus each receiveneural input from both basal ganglia-receiving and cerebellar-receivingcell groups in the thalamus, but each receives input from a uniquecombination of thalamic nuclei.
Key words: pursuit eye movements; saccades; basal ganglia; substantia nigra; cerebellum; frontal eye field; supplementary eye field; thalamus; Cebus monkeys

INTRODUCTION

The frontal eye field (FEF) of macaque monkeys and humans contains two functional subregions. One helps to control rapid gazeshifts from one object of interest to another (saccadic eye movements);the other controls smooth eye movements that are made to trackmoving objects of interest (pursuit eye movements) (Bruce et al.,1985; Lynch, 1987; Bruce, 1990; Keating, 1991; MacAvoy et al.,1991; Gottlieb et al., 1993, 1994; Berman et al., 1996; Petitet al., 1997). We have recently localized a smooth pursuit subregion(FEFsem) and a saccade subregion (FEFsac) within the FEF in Cebusmonkeys (Tian and Lynch, 1996a). Tracer injections into theseregions disclosed that each receives its predominant corticocorticalinput from other regions that are also concerned primarily withinitiation and control of eye movements, including the parietaleye field, supplementary eye field, middle superior temporal area,and principal sulcus region (Tian and Lynch, 1996b). The FEFsemand FEFsac each receive projections from distinctive subregionswithin these other eye fields. We have proposed that these fieldscomprise nodes in a cortical network that function primarily inparallel to control purposive eye movements (Tian and Lynch, 1996b).

In addition to the influence of neural information from other cortical regions, the execution of successful eye movementsdepends heavily on input from the basal ganglia and cerebellumto cortical motor regions. Disorders of the basal ganglia, suchas Parkinson's disease and Huntington's disease, produce eye movementdisorders (Starr, 1967; Leigh et al., 1983; White et al., 1983;Lasker et al., 1987, 1988; Leigh and Zee, 1991; Tian et al., 1991),as do diseases and injuries that affect the cerebellum (Holmes,1917; Westheimer and Blair, 1973; Zee, 1982; Lisberger et al.,1987; Keller, 1989; Pierrot-Deseilligny et al., 1990; Keller andHeinen, 1991; Leigh and Zee, 1991).

Recent evidence suggests that the basal ganglia and cerebellum exert their influence on cortical motor regions via highlyspecific pathways that are relayed through the thalamus, witheach cortical area receiving a unique mixture of thalamocorticalinput (Alexander et al., 1986, 1990; Holsapple et al., 1991; Hooverand Strick, 1993; Lynch et al., 1994; Rouiller et al., 1994; Matelliand Luppino, 1996). However, the thalamocortical input to functionallyidentified subregions within a single cortical oculomotor fieldhas not been studied previously.

The present experiments were designed to investigate and quantify the thalamocortical input to two oculomotor areas in thecortex that are adjacent to each other and that receive parallelinput from four other cortical oculomotor areas but that controlvery different types of eye movements. It was possible that thethalamocortical input to these areas would be relatively parallel,originating in different subregions of the same thalamic nuclei.However, we found the thalamic input to the FEFsem originatedin a very different set of thalamic nuclei than did the inputto the FEFsac. This suggests that the basal ganglia and cerebellummake quite different contributions to the control of pursuit andsaccadic eye movements, respectively.

Parts of this paper have been published previously in an abstract (Tian et al., 1995)

MATERIALS AND METHODS
Three adult male Cebus apella monkeys, weighing from 3.0 to 3.5 kg, were used in the present study. In three hemispheres,the FEFsem was localized and defined with intracortical microstimulationat low levels ( $<=$ 50 µA); in four hemispheres, the FEFsac was similarlydefined. A new anesthetic agent, Telazol (tiletamine HCl withzolazepam HCl; Robbins Scientific, Sunnyvale, CA) (Schobert, 1987),permitted microstimulation-induced smooth eye movements to bediscriminated reliably from saccadic eye movements, so the localizationof the FEFsem did not require the months of behavioral trainingand recording that such localizations normally require in alert,behaving monkeys (Tian and Lynch, 1995, 1996a). Different retrogradelytransported fluorescent dyes were placed within these functionallydefined subregions to study the subcortical, especially the thalamocortical,inputs to the FEFsem and FEFsac. Two additional areas near theFEF, the supplementary eye field (SEF) and the hand/arm regionof the dorsal premotor cortex (PMd), were also injected in onehemisphere. The methods used in this study have been describedpreviously in detail (Tian and Lynch, 1995, 1996a,b) and willbe summarized here.

Surgical procedures. All surgeries were performed under sterile conditions, following National Institutes of Health guidelinesand a research protocol that was reviewed and approved by theInstitutional Animal Care and Use Committee. Most animals werepretreated with dexamethasone (0.5 mg/kg, i.m.) and atropine sulfate(0.04 mg/kg, i.m.) just before surgery. A head holder appliancewas fixed to the skull in a separate procedure. For the head holderinstallation, each animal was initially anesthetized with Ketamine(10 mg/kg, i.m.); surgical anesthesia was maintained with intravenouspentobarbital sodium. For the surgery during acute mapping experiments,each animal was anesthetized with only Telazol (initial dose,20-30 mg/kg, i.m.; supplemental dose, 5-10 mg/kg, i.m.). Bodytemperature was maintained with a heating pad. Vital signs weremonitored, and antibiotics (intramuscular Rocephin or Cefazolin)were given during surgery and recovery.

Electrical stimulation procedures. Animals were immobilized during acute microstimulation mapping experiments by light dosesof Telazol. Telazol anesthesia, at optimal levels, has very littleeffect on electrical stimulus threshold (Hoover and Strick, 1993;Lynch et al., 1994; Tian and Lynch, 1995). We have performed extensivecomparisons between eye movement parameters during microstimulationin trained, behaving monkeys and eye movements evoked by microstimulationin Telazol-anesthetized monkeys and have determined that the velocitiesand durations of evoked eye movements are only minimally affectedby Telazol (Tian and Lynch, 1995, 1996a). Under Telazol anesthesia,eye movements were triggered from the FEF and SEF at thresholdsas low as 10 µA, and arm and hand movements could be triggeredfrom the premotor cortex and primary motor cortex at thresholdsas low as 5 µA.

Glass-coated Elgiloy or platinum-iridium microelectrodes (0.5-3 m $Omega$ impedance at 1 kHz) were used. Electrical stimulation consistedof trains of negative unipolar constant-current pulses. Pulsefrequency was 300 Hz, and pulse width was 0.5 msec; train durationwas normally 100 msec for studying saccadic eye movements and300-500 msec for studying smooth eye movements. Current was monitoredby displaying, on an oscilloscope, the voltage drop across a 1k $Omega$ resistor in series with the microelectrode. "Low thresholdstimulation" was defined as $<=$ 50 µA. Currents from 50 to 150 µAwere routinely used to search for elicited eye movements. Thethreshold level for each stimulation site was then determinedto localize the low threshold areas. Each microelectrode placementon the cortex was photographed through the operating microscopeused in surgery, and the electrode positions were later reconstructedusing a tracing of the pattern of blood vessels on the surfaceof the cortex as a guide (see Fig. 3; Results). During the courseof each microelectrode penetration, we stimulated at intervalsof 300-500 µm.
Fig. 3. Top, A typical microstimulation map within a region including the frontal eye field, the supplementary eye field, and thedorsal premotor cortex of monkey C6, left hemisphere (C6-L). Themap was reconstructed by projecting and tracing a photograph madethrough the operating microscope of the cortical blood vessels(gray) and then plotting the position of each electrode penetrationfrom individual electrode placement photographs. The locationswhere movements were elicited at thresholds <50 µA are indicatedby letters: S, saccade; Sm, smooth eye movement; Tr, trunk musclecontraction; W, wrist flexion or dorsiflexion; W+A, wrist dorsiflexionevoked superficially in cortex plus forearm pronation and abductionevoked deeper in cortex; A, supination of forearm; and O, no response.An asterisk indicates responses evoked at high threshold (>50µA); a circle around a stimulation point indicates the locationof a tracer injection (see also Fig. 4). Bottom, A lateral viewof the hemisphere. The dotted rectangle indicates the locationof the microstimulation map. A, Arcuate sulcus; AS, arcuate spur;C, central sulcus; IP, intraparietal sulcus; L, lunate sulcus;LF, lateral fissure; P, principal sulcus; ST, superior temporalsulcus.
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Eye movement measurements. During acute cortical mapping experiments, a second operating microscope with an attached videocamera was aimed at the eye contralateral to the microstimulation.Eye movements were displayed on a 21 inch television monitor.The total magnification was 12.5×, which aided in the detectionand classification of eye movements. Electrically evoked eye movementswere recorded on videotape for later verification and analysis(Tian and Lynch, 1995, 1996a). The amplitude and duration of eyemovements were measured with a professional video-editing system,from which the velocities of elicited eye movements could be calculated.This method of measurement permitted the simple quantificationof eye movement parameters in the sterile surgery environmentnecessary for the tracer injections. The 30 Hz sampling rate ofthe video equipment caused the duration of saccades to be overestimated.Although these measurements were not as accurate as those thatcan be provided with the magnetic search coil technique, theywere nevertheless more than adequate to permit the statisticaldifferentiation of saccadic and slow eye movements at very highlevels of significance (p < 0.0001; Tian and Lynch, 1995, 1996a).Typical smooth and saccadic eye movement traces are illustratedin Figure 1.
Fig. 1. Typical time-amplitude trajectories of eye movements in a Telazol-anesthetized Cebus monkey (C6) are illustrated for smooth(A) and saccadic (B) eye movements. Measurements of eye positionwere made using video-editing equipment, manually frame by frame.[Modified from Tian and Lynch (1996a) with permission.]
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Tracer injection procedures. After the FEFsem and the FEFsac were localized with low threshold microstimulation, differentfluorescent dyes were placed in the functionally defined regions.In control experiments, the SEF and the hand/arm region of PMdwere also mapped and injected with fluorescent dyes. Four opticallydistinct retrogradely transported fluorescent tracers were usedin this study. These tracers included fast blue (FB), diamidinoyellow (DY), fluororuby [FR; rhodamine conjugated to 10,000 molecularweight (MW) dextrans], and fluorescein (FS) conjugated to 10,000MW dextrans (Kuypers et al., 1980; Keizer et al., 1983; Nanceand Burns, 1990; Schmued et al., 1990). The combination of tracersused in each experimental animal is shown in Table 1. The tracersFB and DY were used at 2% suspension in distilled water, and thetracers FR and FS were used at 10% suspension in distilled water.The latter two tracers were also transported in the anterogradedirection, but those results are not reported here. Approximately0.6 µl of each fluorescent dye was placed at each injection site.All tracers were pressure-injected (Hardy and Lynch, 1992), usinga 1 or 5 µl Hamilton syringe. Each injection was made over a 5min period. Another 10 min were allowed to elapse before removingthe injection needle from the injection site to minimize the spreadof the injected tracers along the needle track.

Table 1. Summary table of tracer injection sites

Monkey Hemisphere FEFsac FEFsem SEFsac PMd

C5 left DY FS FR

C6 left FB DY

C6 right FS FR

C9 left FB FR

DY, Diamidino yellow; FB, fast blue; FR, fluoro-ruby; FS, fluorescein conjugated to dextrans; FEFsac, saccadic subregion ofthe frontal eye field; FEFsem, smooth eye movement subregion ofthe frontal eye field; SEFsac, saccadic subregion of the supplementaryeye field; PMd, hand region of the dorsal premotor cortex.

Histology procedures. Survival times for the four hemispheres used in this study were 15, 19, 14, and 14 d. Each monkey thenreceived a lethal dose of pentobarbital sodium and was perfusedtranscardially with heparinized saline and 4% formaldehyde in0.1 M phosphate buffer. Brains were exposed and blocked stereotaxicallyin the coronal plane. Brain blocks were stored in 4% formaldehydeand increasing concentrations of sucrose. They were then frozenand sectioned at 50 µm in the coronal plane using a sliding microtome.One series of sections at 250 µm intervals was mounted and coverslippedfor fluorescence study. Alternate sections in another series ofsections (adjacent to the fluorescent sections) were stained usingcresyl violet or Weil procedures. Some sections were counterstainedafter the labeled neurons in them had been plotted. In one monkey,sections containing thalamic nuclei were processed with acetylcholinesterase(AChE) histochemistry to aid in the identification of nuclearboundaries.

Neuroanatomical data analysis procedures. Sections were studied with a Leitz Diaplan fluorescence microscope. The labels werehighly discriminable because of their different appearances anddifferent optimal excitation wavelengths. FB and DY fluoresceat an excitation wavelength of 360 nm. FB filled the cytoplasmof the neuron cell body and appeared bright blue. DY filled onlythe nucleus of the neuron cell body and appeared yellow-green.Neurons labeled by FR exhibited a characteristic bright red fillingof the soma and proximal dendrites at a wavelength of 530-560nm, whereas FS-labeled neurons displayed a yellow-green cytoplasmat a wavelength of 495-520 nm.

The localization of the injection sites has been described previously in detail (Tian and Lynch, 1996b). The filled portionsof the injection sites shown in Results (see Figs. 4, 5) representthe dense core of the injection regions immediately surroundingthe needle track, and the dashed line surrounding the dense corerepresents the region in which the fluorescence was too intensefor individual cells to be distinguished. The effective dye uptakezones have been demonstrated to be restricted approximately tothe region of tissue damage produced by the passage of the injectionneedle (Bullier et al., 1984; Condé, 1987). In our experiments,this zone usually had a diameter of ~1 mm. Our injections wereusually at least 1 mm from the edge of a microstimulation-definedfunctional subregion and at least 4 mm from any other dye injection.All injections therefore fell entirely within the cortex of thefunctional area being studied.
Fig. 4. Top, Injection sites in the smooth eye movement subregion of the FEF (section 180) and in the saccadic subregion of the FEF(section 240) in monkey C6 on coronal sections. Single placementsof different fluorescent tracers are within the gray matter ofeach functional subregion of the FEF. Bottom, A lateral view ofthe left hemisphere of monkey C6. The dotted lines indicate thefundi of sulci; the heavy lines indicate the shoulders of sulci.AS, Arcuate spur; Ci, cingulate sulcus; FEFsac, saccadic subregionof the FEF; FEFsem, smooth eye movement subregion of the FEF;IA, inferior arcuate sulcus; P, principal sulcus; SA, superiorarcuate sulcus.
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Fig. 5. Injection sites of the FEFsac (section 280), the SEF (section 220), and the hand area of the PMd (section 350) on coronalsections of monkey C5 (C5-L). Single placements of different fluorescenttracers are within the gray matter of each functional subregionof the FEF. AS, Arcuate spur; C, central sulcus; Ci, cingulatesulcus; FEFsac, saccadic subregion of the FEF; IA, inferior arcuatesulcus; LF, lateral fissure; P, principal sulcus; PMd, dorsalpart of premotor cortex; SA, superior arcuate sulcus; SEF, supplementaryeye field.
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Labeled neurons were plotted in every section of the fluorescent series using a Minnesota Datametrics MD3 digitizer systemcoupled to the microscope stage. After plotting, the coverslipswere removed from every other fluorescent section, and the sectionswere stained with cresyl violet. Cytoarchitectural borders weretherefore determined on some of the same sections in which labeledneurons had been plotted. The alternate fluorescence sectionswere not stained, but cytoarchitectural borders were estimatedusing immediately adjacent sections that had been stained withcresyl violet. Blood vessels were used to align the cresyl violetand fluorescence sections. The cytoarchitectural features of thethalamic nuclei in these sections were studied, and the nuclearborders were traced using a microprojector and a Zeiss Standardresearch microscope with attached drawing tube. The nuclear borderswere then transferred to the plots of the labeled neurons.

The MD3 software provided the capability of counting the labeled cells inside a given region of a plotted section. The desiredregion of a plot was specified by drawing a polygon around itusing a computer mouse. The quantitative measurements of labeledneurons in specific thalamic nuclei in the present study weremade using this technique.

The nomenclature that we have used for the thalamic nuclei is based on the atlas of Olszewski (1952). It does, however, incorporatethe modifications proposed by Holsapple et al. (1991) that divideVLc into two regions, VLcr and VLcc (see Results). The abbreviationsused throughout the text and figures are listed in Table 2.

Table 2. Abbreviations

AChE Acetylcholinesterase

C cerebellum (see Fig. 8)

CbN cerebellar nuclei

DY diamidino yellow

FB fast blue

FR fluoro-ruby

FS fluorescein

GP globus pallidus

GPi internal globus pallidus

SNr substantia nigra pars reticulata

Cerebral Cortex

A arcuate sulcus

AS arcuate spur

C central sulcus

Ci cingulate sulcus

FEF frontal eye field

FEFsac saccadic subregion of the FEF

FEFsem smooth eye movement subregion of the FEF

IA inferior arcuate sulcus

IP intraparietal sulcus

L lunate sulcus

LF lateral fissure

P principal sulcus

PMd dorsal premotor area

SA superior arcuate sulcus

SAC saccadic eye movement subregion of FEF

SEM smooth eye movement subregion of FEF

SEF supplementary eye field

SEFsac saccadic subregion of SEF

ST superior temporal sulcus

Thalamus

AD nucleus anterior dorsalis

AM nucleus anterior medialis

AV nucleus anterior ventralis

Cdc nucleus centralis densocellularis

Cl, CL central lateral nucleus

Cn Md nucleus centrum medianum

Csl nucleus centralis superior lateralis

H habenula

LD nucleus lateralis dorsalis

LG lateral geniculate nucleus

Li nucleus limitans

LP nucleus lateralis posterior

MD nucleus medialis dorsalis

MDdc nucleus medialis dorsalis, pars densocellularis

MDmc, mc nucleus medialis dorsalis, pars magnocellularis

MDmf, mf nucleus medialis dorsalis, pars multiformis

MDpc, pc nucleus medialis dorsalis, pars parvocellularis

MGmc medial geniculate nucleus, pars magnocellularis

MGpc medial geniculate nucleus, pars parvocellularis

PCn, PCN paracentral nucleus

Pf nucleus parafascicularis

Pul L nucleus pulvinaris lateralis

Pul M nucleus pulvinaris medialis

Pul O nucleus pulvinaris oralis

R reticular nucleus

Re nucleus of reuniens

SG suprageniculate nucleus

Sm stria medullaris thalami

TMT mammillothalamic tract

VA nucleus ventralis anterior

VAmc pars magnocellularis of VA

VApc pars parvocellularis of VA

VL nucleus ventralis lateralis

VLc nucleus ventralis lateralis, pars caudalis

VLcc caudal portion of VLc

VLcr rostral portion of VLc

VLm nucleus ventralis lateralis, pars medialis

VLo nucleus ventralis lateralis, pars oralis

VLps nucleus ventralis lateralis, pars postrema

VPI nucleus ventralis posterior inferior

VPL nucleus ventralis posterior lateralis

VPLc nucleus ventralis posterior lateralis, pars caudalis

VPLo nucleus ventralis posterior lateralis, pars oralis

VPM nucleus ventralis posterior medialis

X area X in the VL complex

RESULTS
Tracers were placed in the FEFsac in four hemispheres and in the FEFsem in three hemispheres. Control injections were madein the SEF and the hand/arm region of the PMd in one hemisphere.We will first describe the salient features of the thalamic nucleithat are important in this study, and then we will describe theplacement of the tracers and the distributions of the thalamicneurons that were labeled by these injections.

Cytoarchitecture of thalamic nuclei
Although atlases of the Cebus thalamus have been published (Eidelberg and Saldias, 1960; Manocha et al., 1968), these atlasesdo not include the detailed discussion of the thalamic cytoarchitecturethat is present in the atlas of the Macaca thalamus of Olszewski(1952). We consequently used cresyl violet, AChE, and Weil methods,in conjunction with Olszewski's atlas (1952) and other recentcytoarchitectural descriptions of the thalamus of Macaca (Asanumaet al., 1983a; Schell and Strick, 1984; Jones, 1985; Ilinsky andKultas-Ilinsky, 1987; Matelli et al., 1989; Holsapple et al.,1991; Shook et al., 1991), to characterize and delineate the Cebusthalamic nuclei. In general, we have followed the nomenclatureof Olszewski (1952), although we have incorporated modificationsof the terminology for the divisions of the ventral lateral nucleusthat were proposed by Holsapple et al. (1991).

In this study, we focus on the nuclei of the motor thalamus, including the VA, the VL, area X, the VPL, and the MD. The cytoarchitecture,relative position, and relative sizes of these nuclei in the Cebusmonkey are quite similar to those of the same nuclei in macaquemonkeys (Fig. 2). The VA in both species is divided into two subdivisions,VApc and VAmc. VAmc is characterized by large, darkly stainingneurons that are packed in distinct clusters. VApc contains smaller,more lightly staining neurons. The VLo is characterized by darklystaining round or oval neurons that are grouped in distinct clusters.At caudal levels, VLo borders ventrally with the VPLo, bordersmedially with area X, and borders dorsally with the VLc. The VPLois distinguished by many large, darkly staining multipolar neuronsthat are loosely packed and do not form the dense cell clustersseen in VLo. There is also a larger variability in neuron sizein VPLo than in VLo. The VLc contains smaller and paler neuronsthan those in VLo and VPLo. VLc has a relatively homogeneous appearance,with neurons of more uniform size than in VPLo and without theclustering seen in VLo. Area X is a well-delineated zone of small,lightly staining neurons with a very homogeneous appearance. MDis easily distinguished from the other nuclei by the internalmedullary lamina and the darkly staining neurons of the adjacentintralaminar nuclei. Four subdivisions of MD are commonly distinguishedin macaque: MDpc, MDmc, MDmf, and MDdc (Olszewski, 1952;Goldman-Rakicand Porrino, 1985; Barbas et al., 1991). We have found the samesubdivisions to be clearly distinguishable in the Cebus monkey,although MDmf is not as easily delineated as in macaque.
Fig. 2. Macrophotographs of cresyl violet-stained sections from the thalamus of Cebus monkey C9. Section 450 is at the most rostrallevel; 540 is at the most caudal level. See Results for descriptionsof nuclei and cytoarchitectural features. AD, Anterior dorsalis;AM, anterior medialis; AV, anterior ventralis; CL, central lateralnucleus; Cn Md, centrum medianum; LD, lateralis dorsalis; MD,medialis dorsalis; MDmc or mc, medialis dorsalis, pars magnocellularis;MDpc or pc, medialis dorsalis, pars parvocellularis; PCN, paracentralnucleus; R, reticular nucleus; TMT, mammillothalamic tract; VAmc,ventralis anterior, pars magnocellularis; VApc, ventralis anterior,pars parvocellularis; VLcc, caudal portion of ventralis lateralis,pars caudalis; VLcr, rostral portion of ventralis lateralis, parscaudalis; VLo, ventralis lateralis, pars oralis; VPI, ventralisposterior inferior; VPLo, ventralis posterior lateralis, parsoralis; VPM, ventralis posterior medialis; X, area X in the ventrallateral complex.
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Holsapple et al. (1991) have divided the VLc into two subdivisions, VLcr and VLcc, on the basis of differing connectivitywith the cerebellum and basal ganglia. This is an important distinctionbecause VLcr receives a major input from the globus pallidus (Kuoand Carpenter, 1973; DeVito and Anderson, 1982), whereas the predominantinput to VLcc is from the cerebellum (Percheron, 1977; Stanton,1980; Kalil, 1981; Asanuma et al., 1983b). There are no clearcytoarchitectural differences between VLcr and VLcc, but the anatomicalstudies cited above suggest that VLcr lies rostral to anteriorlevel 7.1 in Olszewski's atlas (1952), which corresponds approximatelyto anterior level 7.5 in the Eidelberg and Saldias atlas of theCebus monkey (1960) and approximately to section 520 in monkeyC9 of the present study (just posterior to section 510 in Fig.2).

Tracer placements
The localization of the major functional regions in the periarcuate cortex using microstimulation has been described previouslyin detail (Tian and Lynch, 1995, 1996a). In these experiments,a limited number of microelectrode penetrations were made in mostanimals to localize each tracer placement definitively withinthe boundaries of the respective functional region, while preserving,as much as possible, the integrity of the tissue for later cytoarchitecturalstudy (Fig. 3). The smooth eye movement subregion was reliablylocated in a small area classically defined as 6A $beta$ (Vogt and Vogt,1919) and more recently as 6DR (Barbas and Pandya, 1987) or F7(Matelli et al., 1991). This region is in the posterior shoulderof the arcuate sulcus, near its medial tip (Figs. 3, 4). The saccadicsubregion of the FEF in Cebus was localized on the anterior bankof the arcuate sulcus and the rostrally adjacent surface cortex,in areas 8a and 45 of Walker (1940) (Figs. 3, 4; see also Tianand Lynch, 1996a, their Figs. 3, 4, 5).

Typical injection sites in the FEFsac and the FEFsem are illustrated in Figure 4. The shaded areas in the drawing of the arcuatesulcus region (Fig. 4, bottom) indicate the sum of the locationsof all penetrations in all Cebus monkeys in our laboratory overthree years (including animals reported in Tian and Lynch 1995,1996a,b) that produced a given type of eye movement (smooth orsaccadic). The levels of the two injection site sections are indicatedby vertical lines in the drawing of the arcuate sulcus region.

In one hemisphere, the tracers DY, FS, and FR were placed in the FEFsac (section 280), the SEF (section 220), and the hand/armarea of the PMd (section 350), respectively (Fig. 5). This combinationof tracer placements was used to compare the origin of thalamicinputs to three functionally distinct cortical regions that areimmediately adjacent to the smooth eye movement subregion. Microstimulationat the PMd injection site in this monkey produced pronation ofthe forearm and flexion of the wrist.

Distribution of labeled thalamocortical neurons
Thalamic input to the smooth eye movement subregion of the FEF Neurons labeled by injections in the FEFsem were primarily in the most dorsal part of several thalamic nuclei including VLc,VA, and MD (Fig. 6, blue dots; see also Figs. 8, 9B). At rostrallevels, labeled neurons were distributed in both the VApc andthe VAmc. Throughout the anteroposterior extent of VLc, a largegroup of labeled neurons was tightly clustered in the most dorsalpart of the nucleus. The FEFsem-labeled neurons in MD were predominantlyclustered in the most dorsal portion of MDpc, and their distributionoverlapped only slightly with that of FEFsac-labeled neurons.Only in the most posterior portion of MD were the FEFsem and FEFsacneurons somewhat intermixed (sections 991 and 971). Neurons labeledfrom the FEFsem injections were also scattered in Pcn and Cl.This distribution was reasonably consistent in two different monkeysusing two different tracers (see Fig. 9B).
Fig. 6. The origin of thalamic inputs to the FEFsem (blue dots) and FEFsac (red dots) in the left hemisphere of monkey C6 on coronalsections (C6-L). Section 1091 is at the most rostral level, andsection 971 is at the most caudal level. The fluorescent tracersFB and DY were injected into the FEFsac and the FEFsem, respectively(see Table 1 and Fig. 4). A total of 31 sections at 250 µm intervalswere plotted. AD, Anterior dorsalis; AM, anterior medialis; AV,anterior ventralis; Cdc, centralis densocellularis; Cl, centrallateral nucleus; Cn Md, centrum medianum; Csl, centralis superiorlateralis; H, habenula; LD, lateralis dorsalis; LG, lateral geniculatenucleus; Li, nucleus limitans; LP, lateralis posterior; MD, medialisdorsalis; MDdc, medialis dorsalis, pars densocellularis; MDmc,medialis dorsalis, pars magnocellularis; MDmf or mf, medialisdorsalis, pars multiformis; MDpc, medialis dorsalis, pars parvocellularis;MGmc, medial geniculate nucleus, pars magnocellularis; MGpc, medialgeniculate nucleus, pars parvocellularis; Pcn, paracentral nucleus;Pf, parafascicularis; Pul L, pulvinaris lateralis; Pul M, pulvinarismedialis; Pul O, pulvinaris oralis; R, reticular nucleus; SG,suprageniculate nucleus; Sm, stria medullaris thalami; VAmc, ventralisanterior, pars magnocellularis; VApc, ventralis anterior, parsparvocellularis; VLc, ventralis lateralis, pars caudalis; VLcc,caudal portion of VLc; VLcr, rostral portion of VLc; VLm, ventralislateralis, pars medialis; VLo, ventralis lateralis, pars oralis;VLps, ventralis lateralis, pars postrema; VPI, ventralis posteriorinferior; VPLc, ventralis posterior lateralis, pars caudalis;VPLo, ventralis posterior lateralis, pars oralis; VPM, ventralisposterior medialis; X, area X in the ventral lateral complex.
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Fig. 8. Quantitative comparison of distribution patterns of labeled neurons in thalamic nuclei from the four cortical injection sites.Labeled neurons were counted within the cytoarchitectural boundariesof 31 sections spaced at 250 µm intervals in monkeys C5 and C6.Each graph illustrates the percentage, in each nucleus, of thetotal number of neurons labeled by that particular injection.The thalamic nuclei are arranged on the x-axis so that regionsthat receive input from the internal segment of the globus pallidusand the pars reticulata of the substantia nigra are on the leftof the vertical dashed line and the nuclear regions that receiveinput from the cerebellar nuclei are on the right of the dashedline. The medial dorsal nucleus receives input from both the basalganglia and the cerebellum. Intralaminar nuclei (Pcn and Cl),indicated by IML, and the Pul M are not included in the basalganglia versus cerebellum distribution dichotomy. A total of 5692neurons were labeled by the FEFsac injection, 2876 by the FEFseminjection, 460 by the SEFsac injection, and 1288 by the PMd injection.C, Cerebellum, predominantly via the dentate nucleus; FEFsac,saccadic subregion of the frontal eye field; FEFsem, smooth eyemovement subregion of the frontal eye field; GP, globus pallidus;IML, intralaminar nuclei; MD, medialis dorsalis; PMd, hand regionof the dorsal premotor cortex; Pul M, pulvinaris medialis; SEFsac,saccadic subregion of the supplementary eye field; SNr, substantianigra pars reticularis; VAmc, ventralis anterior, pars magnocellularis;VApc, ventralis anterior, pars parvocellularis; VLcc, caudal portionof ventralis lateralis, pars caudalis; VLcr, rostral portion ofventralis lateralis, pars caudalis; VLo, ventralis lateralis,pars oralis; VPLo, ventralis posterior lateralis, pars oralis;X, area X of ventral lateral complex.
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Fig. 9. A, Comparison of the thalamic distributions of FEFsac-labeled neurons in three monkeys. B, Comparison of the thalamic distributionsof FEFsem-labeled neurons in two monkeys. Each graph illustratesthe percentage, in each nucleus, of the total number of neuronslabeled by that particular injection. In the inset in A, the numbers(5, 6, and 9) show the relative positions of the three FEFsacinjection sites on a standardized drawing of the arcuate sulcusregion for monkeys C5, C6, and C9, respectively. Tracers wereDY in C5, FB in C6, and FB in C9. In the inset in B, the two circlesindicate the relative positions of the FEFsem injections in monkeysC6 and C9. Tracers were DY in C6 and FR in C9. The thalamic nucleiare arranged on the x-axis so that regions that receive inputfrom the internal segment of the globus pallidus and the parsreticulata of the substantia nigra are on the left of the MD andthe nuclear regions that receive input from the cerebellar nucleiare on the right of the MD. The medial dorsal nucleus receivesinput from both the basal ganglia and the cerebellum. A, Arcuatesulcus; CL, central lateral nucleus; Li, nucleus limitans; MD,medialis dorsalis; P, principal sulcus; Pcn, paracentral nucleus;Pul M, pulvinaris medialis; VAmc, ventralis anterior, pars magnocellularis;VApc, ventralis anterior, pars parvocellularis; VLcc, caudal portionof ventralis lateralis, pars caudalis; VLcr, rostral portion ofventralis lateralis, pars caudalis; VLo, ventralis lateralis,pars oralis; VPLo, ventralis posterior lateralis, pars oralis;X, area X in the ventral lateral complex.
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Thalamic input to the saccadic eye movement subregion of the FEF Neurons labeled by injections in the FEFsac were much more heavily concentrated in the paralaminar region of MD (both MDmfand MDpc) than in any other thalamic nucleus (Figs. 6, 7, reddots; see also Figs. 8, 9A). Descriptions of the size of the multiformregion of MD (MDmf) in macaques have ranged from relatively small(Goldman-Rakic and Porrino, 1985; Barbas et al., 1991) to quitelarge, incorporating almost the entire paralaminar region (Siwekand Pandya, 1991). In Cebus monkeys, the zone that can be definitelyclassified as MDmf, with characteristic large, darkly stainingcells, is quite small. Most neurons labeled by FEFsac injectionswere therefore clearly within the paralaminar zone of MDpc. Labeledneurons were also densely packed within the intralaminar nucleiPcn and Cl. Both of these nuclei are known to receive strong projectionsfrom the dentate nucleus (Chan-Palay, 1977) and have been implicatedin the control of purposeful as well as spontaneous eye movements(Schlag-Rey and Schlag, 1977, 1984; Schlag et al., 1980; Schlagand Schlag-Rey, 1984). A small number of labeled neurons was alsoobserved in VApc, VAmc, VLo, VLc, area X, the medial pulvinarnucleus, and the nucleus limitans (Figs. 8, 9A). This generaldistribution was remarkably consistent in three different monkeysand for two different tracers (Fig. 9A).
Fig. 7. The origin of thalamic inputs to the FEFsac, SEF, and PMd in the left hemisphere of monkey C5 on coronal sections (C5-L) (seeTable 1 for fluorescent tracers used in these injections). Section1111 is at the most rostral level, and section 1041 is at themost caudal level. A total of 31 sections at 250 µm intervalswere plotted. Red dots indicate the neurons labeled from an injectionsite in the FEFsac; black dots indicate the neurons labeled froman injection site in the SEF; and light blue dots indicate theneurons labeled from an injection site of the PMd (hand). AD,Anterior dorsalis; AV, anterior ventralis; Cdc, centralis densocellularis;Cl, central lateral nucleus; Cn Md, centrum medianum; Csl, centralissuperior lateralis; LD, lateralis dorsalis; MDmc, medialis dorsalis,pars magnocellularis; mf, medialis dorsalis, pars multiformis;MDpc, medialis dorsalis, pars parvocellularis; Pcn, paracentralnucleus; R, reticular nucleus; Re, nucleus of reuniens; Sm, striamedullaris thalami; VAmc, ventralis anterior, pars magnocellularis;VApc, ventralis anterior, pars parvocellularis; VLc, ventralislateralis, pars caudalis; VLcc, caudal portion of VLc; VLcr, rostralportion of VLc; VLm, ventralis lateralis, pars medialis; VLo,ventralis lateralis, pars oralis; VPI, ventralis posterior inferior;VPLc, ventralis posterior lateralis, pars caudalis; VPLo, ventralisposterior lateralis, pars oralis; VPM, ventralis posterior medialis;X, area X in the ventral lateral complex.
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Thalamic input to the SEF and the PMd The supplementary eye field and the hand/arm region of the dorsal premotor cortex both lie very close to the smooth eye movementsubregion in the Cebus monkey. The thalamic input to both theSEF and the PMd have been studied extensively in the macaque monkeybut not in the Cebus. To compare the thalamocortical input tothe SEF and the PMd with the thalamocortical input to the closelyadjacent FEFsem and also to compare the thalamocortical inputto the SEF and the PMd in Cebus with that in Macaca, we made tracerinjections in the SEF and the PMd in one hemisphere (Fig. 7).

Most neurons labeled by the SEF dye placement were clustered in area X of the ventral lateral complex (Fig. 7, black dots;see also Fig. 8). Labeled neurons were also observed in the VAnucleus, predominantly in the VApc. Some labeled neurons wereseen in VLcr and in MD, a few labeled neurons were scattered withinVLo at rostral levels, and a few labeled neurons were also seenin Cl. The SEF thus receives major thalamocortical input fromboth a basal ganglia target (VApc) and a cerebellar target (X)(Figs. 8, 10).
Fig. 10. Summary diagram of GPi- and SNr-thalamocortical and cerebellothalamocortical connection patterns. A, Putative circuits frombasal ganglia and cerebellum through thalamic nuclei to the FEFsacand FEFsem. B, Putative circuits from basal ganglia and cerebellumthrough thalamic nuclei to the SEF and PMd. Each of the functionalareas in the cerebral cortex receives a major neural input fromboth a basal ganglia-receiving and a cerebellar-receiving cellgroup in the thalamus. It is proposed that some neurons from thebasal ganglia and cerebellar nuclei synapse on thalamic neuronsthat, in turn, project to the cortical eye fields. However, thisspecific connectivity has thus far been confirmed with transneuronaltransport experiments only in the case of the FEFsac (Lynch etal., 1994). The terms "dorsal" and "ventral" are used with theVLcr and VLcc nuclei to emphasize the fact that even though boththe FEFsem and the PMd receive input from these two nuclei, therespective pathways originate in separate subregions of thesenuclei. Similarly, the term "dorsal MD" is used to emphasize thatthe MD projection to the FEFsem originates in the dorsal-mostportion of paralaminar MD, whereas the MD projection to the FEFsacoriginates relatively more ventrally in paralaminar MD. CbN, Cerebellarnuclei; FEF, frontal eye field; FEFsac, saccadic subregion ofthe FEF; FEFsem, smooth eye movement subregion of the FEF; GPi,internal globus pallidus; MD, medialis dorsalis; PMd, dorsal premotorcortex; SEF, supplementary eye field; SNr, substantia nigra, parsreticulata; VAmc, ventralis anterior, pars magnocellularis; VApc,ventralis anterior, pars parvocellularis; VLcc, caudal portionof ventralis lateralis, pars caudalis; VLcr, rostral portion ofventralis lateralis, pars caudalis; VLo, ventralis lateralis,pars oralis; VPLo, ventralis posterior lateralis, pars oralis;X, area X in the ventral lateral complex.
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The majority of the neurons labeled by the PMd dye placement were located in VLo, VLcr, VLcc, and VPLo (Fig. 7, light bluedots; see also Fig. 8). The labeled neurons in VLcr and VLcc werelocated in general more ventrally in the nucleus than were theclusters of FEFsem neurons that were also observed in VLcr andVLcc in hemispheres C6-R, C6-L, and C9-L. Thalamocortical neuronsthat projected to PMd were thus located in target areas of thebasal ganglia (VLcr, VLo) as well as in target areas of the cerebellum(VLcc, VPLo) (Figs. 8, 10).

The overall distributions of the cells of origin of the thalamocortical input to the four functionally defined cortical areasstudied in these experiments are therefore markedly differentfrom each other (Fig. 8). However, each cortical area receivesinput from thalamic targets of both the basal ganglia and thecerebellum. The distributions that we have described for neuronsthat project to FEFsac were consistent in three different animalsand with two different tracers (Fig. 9A). The injections in allthree of these animals were placed near the middle of the FEFsac(see inset). No reliable differences were seen that were relatedto the mediolateral positions of the injection sites. However,all three injections were within the middle third of the usualextent of the FEFsac. There was somewhat more variation in therelative distributions of the neurons that projected to the FEFsem(Fig. 9B) than in the distributions of the neurons that projectedto the FEFsac (Fig. 9A). Nevertheless, the basic pattern of theFEFsem-neuron distributions was the same for both animals (Fig.9B).

DISCUSSION
There is steadily increasing evidence that the neural pathways mediating the influence of the basal ganglia and cerebellumon motor activity in the cerebral cortex are highly specializedand are different for different types of motor behaviors and differentcortical areas. In important review papers, Alexander et al. (1986,1990) have proposed that there are at least four distinct cortex-basalganglia-cortex "circuits" or "loops": a "motor" loop related toprecentral somatomotor cortex, an "oculomotor" loop related tothe frontal eye field, a "prefrontal" loop related to dorsolateralprefrontal and lateral orbitofrontal cortex, and a "limbic" looprelated to anterior cingulate and medial orbitofrontal cortex.Each circuit is thought to involve separate, functionally independentregions of the basal ganglia and thalamus. They have further suggestedthat within each major circuit there are segregated "channels,"each of which subserves one specific aspect of the related function.For example, the globus pallidus contains distinct, spatiallysegregated populations of neurons that project, respectively,to primary motor cortex, the supplementary motor area, and ventralpremotor cortex via separate, nonoverlapping regions within VLo(Hoover and Strick, 1993). Thus, pallidal channels directed tothe primary motor cortex may subserve a completely different aspectof motor control than do pallidal channels directed toward thesupplementary motor area. Cortical-cerebellar-cortical circuitsseem to be similarly specialized. For example, neurons in themost posterior and ventral portion of the dentate nucleus werelabeled transneuronally by herpesvirus placed in the FEF (Lynchet al., 1994), whereas dentate neurons labeled by virus placementsjust anterior to the FEF in adjacent cortical area 46 occupy themiddle third of the inferior portion of that nucleus (Middletonand Strick, 1994).

The oculomotor system provides an excellent model to test hypotheses concerning separate channels within a given subcortical-corticalloop circuit. The FEF contains two distinct subregions. One (FEFsem)participates in the control of smooth pursuit eye movements, withthe attendant demand for constant feedback control of eye positionand velocity (Lynch, 1987; Keating, 1991). The second (FEFsac)participates in the control of saccadic eye movements, which aremore nearly all-or-none, precalculated ballistic eye movements(Bruce and Goldberg, 1985; Bruce et al., 1985) and thus do notrequire neural feedback during the course of an individual movement.The comparison of the thalamic inputs to these two cortical subregionscan give important information about the relative participationof the basal ganglia and cerebellum in the function of the FEFin the control of pursuit and saccadic eye movements. However,in macaque monkeys (the usual subject in physiological and anatomicaloculomotor studies), the FEFsem is located in the very bottomof the deep arcuate sulcus and thus constitutes a difficult targetfor accurate tracer injections (MacAvoy et al., 1991; Gottliebet al., 1993, 1994).

We have recently localized the FEFsem in the Cebus monkey and found it to be on the posterior shoulder of the arcuate sulcuswhere it can be more accurately injected with anatomical tracers(Tian and Lynch, 1996a). Tracer experiments demonstrated thatthe FEFsem and the FEFsac are connected in parallel to separatesubregions of each of four other cortical eye fields (Tian andLynch, 1996b). These anatomical results support recent proposalsthat the cortical control of eye movements is not organized asa serial process, originating in the primary visual cortex andculminating in the frontal eye field, but rather is mediated bytwo parallel networks of cortical eye fields that control purposefulpursuit and saccadic eye movements in a cooperative way (Lynch,1992; Barton et al., 1996; Tian and Lynch, 1996b). Similar proposalshave been made for corticocortical networks to subserve workingmemory, spatially guided behavior, and other cognitive functions(Goldman-Rakic, 1988; Selemon and Goldman-Rakic, 1988; Mesulam,1990; Friedman and Goldman-Rakic, 1994; Bressler, 1995; Klingberget al., 1997). However, even when a function such as eye movementcontrol is distributed across several nodes in a network, eachnode probably makes its own special contribution to the functionof the network as a whole.

How might the basal ganglia and cerebellar loops affect the FEFsem and FEFsac subregions independently? One obvious differenceis that the FEFsem receives a considerably richer input from theglobus pallidus targets in the thalamus than does the FEFsac.In the past, most studies of basal ganglia and eye movements havefocused on saccadic eye movements (Hikosaka and Wurtz, 1983a,b,c,d;Hikosaka, 1989; Hikosaka and Wurtz, 1989; Kato et al., 1995; Koriet al., 1995). To our knowledge, no recording studies in behavingsubhuman primates have looked directly at the role of the basalganglia in visual pursuit. However, visual pursuit is often impairedin humans with idiopathic Parkinson's disease (White et al., 1983)as well as in humans with MPTP-induced Parkinsonism (Hotson etal., 1986). Furthermore, a recent functional magnetic resonanceimaging study has observed increased activity in the putamen ofsubjects performing visual pursuit tasks but not saccade tasks(Berman et al., 1996) (J. A. Sweeney, personal communication).In our present study, FEFsem injections labeled thalamic targetsof both the globus pallidus and SNr, whereas FEFsac injectionslabeled only a thalamic target of the SNr. This suggests thatthe caudate, putamen, and globus pallidus play an important rolein the control of visual pursuit. Furthermore, because the SNrprojects to thalamic nuclei that, in turn, project to the FEFsem,it may also participate in the control of visual pursuit in additionto its well known role in the control of saccadic eye movements(Hikosaka, 1989; Hikosaka and Wurtz, 1989).

Recent evidence suggests that each functional subregion of the cortical somatomotor system receives input from both the basalganglia and the cerebellum (Holsapple et al., 1991; Yamamoto etal., 1992; Hoover and Strick, 1993; Rouiller et al., 1994; Matelliand Luppino, 1996). For example, Holsapple et al. (1991) demonstratedthat the hand region of primary motor cortex can basal gangliainput via the nucleus ventralis lateralis, pars oralis, and cerebellarinput via nucleus ventralis posterior lateralis, pars oralis.Similarly, Matelli and Luppino (1996) have observed that differentfunctional subregions within cytoarchitectural area 6 (premotorand supplementary motor cortex) each receive thalamic input fromboth basal ganglia relay nuclei and cerebellar relay nuclei inthe thalamus.

Our results demonstrate that each of the eye fields of the frontal cortex (FEFsem, FEFsac, and SEF), as well as the dorsalpremotor cortex (PMd), receive input from both basal ganglia andcerebellum (Figs. 9, 10). We have demonstrated that the FEFsemreceives thalamocortical input from VApc and VLcr, nuclei thatreceive input from the globus pallidus (Nauta and Mehler, 1966;Kuo and Carpenter, 1973; Kim et al., 1976; DeVito and Anderson,1982). The FEFsem also receives input from VAmc and MD. Thesenuclei are targets of the substantia nigra (Carpenter and McMasters,1964; Carpenter and Strominger, 1967; Carpenter and Peter, 1972;Carpenter et al., 1976, 1981; Ilinsky et al., 1985; Ilinsky andKultas-Ilinsky, 1987).

The FEFsem also receives a large percentage of its thalamocortical input from VLcc and MD (Figs. 9, 10). These nuclei are targetsof cerebellum projections, originating predominantly in the dentatenucleus (Kusama et al., 1971; Kievit and Kuypers, 1972; Kuo andCarpenter, 1973; Batton et al., 1977; Chan-Palay, 1977; Percheron,1977; Stanton, 1980; Kalil, 1981; DeVito and Anderson, 1982; Asanuma,1983b,c). The dentate nucleus, in turn, receives its cerebellarinput from the hemispheres and paraflocculus (Jansen and Brodal,1940, 1942; Nagao, 1992; Nagao et al., 1992). In contrast, thefastigial nucleus, which has been intensively studied with respectto eye movement control, has only modest projections to the thalamus(Blanks, 1988; Noda et al., 1990; Leichnetz and Gonzalo-Ruiz,1996). It does, however, have extensive connections to the brainstemoculomotor system (Batton et al., 1977; Gonzalo-Ruiz et al., 1988;Noda et al., 1990; Leichnetz and Gonzalo-Ruiz, 1996). Thus thecerebellar vermis and related fastigial nucleus seem to exerttheir primary oculomotor influence at the brainstem level, whereasthe dentate nucleus and associated cerebellar hemispheres andparaflocculus are the primary participants in the cortex-cerebellum-thalamus-cortexcircuits.

The predominant input to the FEFsac in Cebus monkeys is from the paralaminar area of the MD nucleus (Figs. 9, 10). This regionis known to receive input from the SNr, dentate nucleus of thecerebellum, and superior colliculus (Harting et al., 1980: Ilinskyet al., 1985; Ilinsky and Kultas-Ilinsky, 1987; Yamamoto et al.,1992). Furthermore, recent experiments have demonstrated thatherpesvirus placed in the FEF is transported transneuronally tothe SNr, the dentate, and the superior colliculus (Lynch et al.,1994). These three structures each have major roles in the controlof saccadic eye movements.

In summary, our results demonstrate that both the pursuit and the saccadic subregions of the frontal eye field receive connectionsfrom both basal ganglia targets and cerebellar targets in thethalamus. However, the exact pathway taken by the basal ganglia-thalamus-FEFsemcircuit is anatomically distinct from the pathway taken by thebasal ganglia-thalamus-FEFsac circuit. Similarly, the cerebellum-thalamus-FEFsemcircuit is anatomically distinct from the cerebellum-thalamus-FEFsaccircuit.

FOOTNOTES

Received Jan. 2, 1997; revised Sept. 11, 1997; accepted Sept. 15, 1997.

This research was supported by Public Health Service Grant 2-R01-EY-04159 and the Joe Weinberg Research Fund (J.C.L.). Weare very grateful to Jerome Allison, Becky Massey, Bill Bedinger,Dong-mei Cui, Hao Liu, and David Lynch for their assistance inthe experiments, data analysis, and illustrations; to Sandy Ruckstuhlfor help in editing this manuscript; and to the personnel of theUniversity of Mississippi Medical Center Television Studio fortheir assistance in measuring the eye movements. We thank Dr.Peter Strick for assistance in defining thalamic nuclear bordersin Cebus monkeys, Drs. Peter Strick and Gregory Mihailoff forhelpful comments on earlier versions of this manuscript and Dr.James Hutchins for assistance in neurohistochemical procedures.

This material has been presented by J.-R. T. in partial fulfillment of the requirements for the degree of Doctor of Philosophy.

Correspondence should be addressed to Dr. James C. Lynch, Department of Anatomy, University of Mississippi Medical Center,2500 North State Street, Jackson, MS 39216-4505.

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