The Inferior Parietal Lobule Is the Target of Output from the Superior Colliculus, Hippocampus, and Cerebellum

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The Journal of Neuroscience, August 15, 2001, 21(16):6283-6291

The Inferior Parietal Lobule Is the Target of Output from the Superior Colliculus, Hippocampus, and Cerebellum
Dottie M. Clower¹^,², Robert A. West³, James C. Lynch⁴, and Peter L. Strick¹^,²
¹ Research Service, Veterans Administration Medical Center, Pittsburgh, Pennsylvania 15261, ² Departments of Neurobiology, Neurological Surgery, and Psychiatry and Center for the Neural Basis of Cognition, University of Pittsburgh, Pittsburgh, Pennsylvania 15261, ³ Department of Physiology, State University of New York Health Science Center at Syracuse, and Central New York Research Corporation, Syracuse Veterans Affairs Medical Center, Syracuse, New York 13210, and ⁴ Departments of Anatomy, Ophthalmology, and Neurology, University of Mississippi Medical Center, Jackson, Mississippi 39216

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The inferior parietal lobule (IPL) is a functionally and anatomically heterogeneous region that is concerned with multipleaspects of sensory processing and sensorimotor integration. Althoughconsiderable information is available about the corticocorticalconnections to the IPL, much less is known about the origin andimportance of subcortical inputs to this cortical region. To examinethis issue, we used retrograde transneuronal transport of theMcIntyre-B strain of herpes simplex virus type 1 (HSV1) to identifythe second-order neurons in subcortical nuclei that project tothe IPL. Four monkeys (Cebus apella) received injections of HSV1into three different subregions of the IPL. Injections into aportion of the lateral intraparietal area labeled second-orderneurons primarily in the superficial (visual) layers of the superiorcolliculus. Injections of HSV1 into a portion of area 7a labeledmany second-order neurons in the CA1 region of the hippocampus.In contrast, virus injections within a portion of area 7b labeledsecond-order neurons in posterior regions of the dentate nucleusof the cerebellum. These observations have some important functionalimplications. The IPL is known to be involved in oculomotor andattentional mechanisms, the establishment of maps of extrapersonalspace, and the adaptive recalibration of eye-hand coordination.Our findings suggest that these functions are subserved by distinctsubcortical systems from the superior colliculus, hippocampus,and cerebellum. Furthermore, the finding that each system appearsto target a separate subregion of the IPL provides an anatomicalsubstrate for understanding the functional heterogeneity of theIPL.

Key words: posterior parietal cortex; LIP; area 7a; area 7b; dentate nucleus; oculomotor

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The inferior parietal lobe (IPL) is thought to be involved in a diverse set of neural operations, including spatial attention,multimodal sensory integration, and oculomotor control (Lynch,1980; Hyvarinen, 1981). Electrophysiological studies have demonstratedthat neurons in IPL have response properties ranging from attention-enhancedvisual and oculomotor responses (Lynch et al., 1977; Goldberget al., 1990; Colby et al., 1996) to complex patterns of activityduring object visualization and manipulation (Sakata et al., 1995;Murata et al., 1996). Some of these properties have led to theconcept that IPL participates in building multiple spatial representationsfor the guidance of both eye and limb movements (Andersen, 1989;Colby and Goldberg, 1999).

Anatomical evidence indicates that IPL is a heterogeneous structure, with subregions characterized by unique patterns of corticaland subcortical connections (Pandya and Seltzer, 1982; Asanumaet al., 1985; May and Andersen, 1986; Cavada and Goldman-Rakic,1989a,b, 1991; Andersen et al., 1990; Lewis and Van Essen, 2000).For example, the lateral intraparietal area (LIP) is extensivelyinterconnected with the frontal eye field (FEF), as well as withother visual cortical areas, and projects heavily to the intermediatelayers of the superior colliculus (Barbas and Mesulam, 1981; Lynchet al., 1985; Andersen et al., 1990). Another subregion of IPL,area 7b, is preferentially connected to somatosensory areas Iand II and the ventral premotor area (PMv) (Cavada and Goldman-Rakic,1989a,b; Andersen et al., 1990). A third subregion of IPL, area7a, shows little connectivity to FEF and no projection to thesuperior colliculus (Lynch et al., 1985; Andersen et al., 1990);yet area 7a has stronger connectivity to the dorsolateral prefrontalcortex than has either LIP or area 7b (Cavada and Goldman-Rakic,1989b). It is likely that the functional subdivisions in IPL reflect,in part, this differentialconnectivity.

Little is known about the subcortical inputs to different subregions of IPL. Thalamic inputs to LIP, area 7a, and area 7bare known to be distinct (Asanuma et al., 1985; Schmahmann andPandya, 1990; Hardy and Lynch, 1992). Such segregation of thethalamic projections suggests that the subdivisions of IPL receiveunique patterns of subcortical inputs as well. However, the disynapticnature of these connections has made it difficult to define thesepathways. Therefore, we used retrograde transneuronal transportof the McIntyre-B strain of herpes simplex virus type 1 (HSV1)to determine subcortical inputs to portions of LIP, area 7a, andarea 7b. There are two major results of this study. First, wefound that the IPL is the target of disynaptic outputs from thesuperior colliculus, hippocampus, and cerebellum. Second, eachof these subcortical nuclei projects to a different subregionof theIPL.

Parts of this paper have been published previously in abstract form (West et al., 1998, 1999).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This report is based on observations from four juvenile Cebus apella monkeys. The McIntyre-B strain of HSV1 was injected intodifferent portions of the inferior parietal cortex in four hemispheres.This strain of HSV1 travels transneuronally in the retrogradedirection in a time-dependent manner (Zemanick et al., 1991; Strickand Card, 1992; Hoover and Strick, 1999). The procedures adoptedfor this study and the care provided experimental animals conformedto the regulations detailed in the National Institutes of HealthGuide for the Care and Use of Laboratory Animals. All protocolswere reviewed and approved by the Institutional Animal Care andUse committees. The biosafety precautions taken during these experimentsconformed to or exceeded biosafety level 2 (BSL-2) regulationsdetailed in Biosafety in Microbiological and Biomedical Laboratories(Health and Human Services Publication 93-8395). A detailed descriptionof the procedures for handling virus and virus-infected animalsis presented in Strick and Card (1992) and Hoover and Strick (1999).

Surgery. Twelve hours before surgery, each animal was administered dexamethasone (Decadron, 0.5 mg/kg, i.m.) and restrictedfrom food and water. Approximately twenty minutes before anesthesiawas initiated, animals were pretreated with either atropine sulfate(0.05 mg/kg, i.m.) or glycopyrrolate (0.01 mg/kg, i.m.). Mostof the animals were anesthetized initially with ketamine hydrochloride(Ketalar, 15-20 mg/kg, i.m.), intubated, and maintained undergas anesthesia using a 1:1 mixture of isoflurane (Enflurane) andnitrous oxide (1.5-2.5%; 1-3 l/min). Other animals were anesthetizedwith Telazol (initial dose, 20 mg/kg, i.m.; supplemental dose,5-7 mg · kg¹ · hr¹, i.m.). In these cases, the analgesic butorphenol (Torbugesic,0.1-0.4 mg/kg, i.m.) was given every 2-4 hr to reduce the overallamount of Telazol used. After being anesthetized, all animalswere administered dexamethasone (0.5 mg/kg, i.m.) and an antibiotic[cefazolin sodium (Kefzol, 25 mg/kg, i.m.) or ceftriaxone (Rocephin,75 mg/kg, i.m.)]. Hydration was maintained using lactated Ringer'ssolution with 5% dextrose (6-10 cc/hr, i.v.), and temperaturewas maintained with a heating pad. Heart rate, blood oxygen saturation,body temperature, and respiratory depth were continuously monitoredduring thesurgery.

All surgical procedures were conducted using aseptic techniques. Each animal's head was positioned in a stereotaxic frame(Kopf). Ophthalmic ointment was placed in the eyes. A craniotomywas performed over the parietal lobe, and the dura was incisedand reflected to expose the region of interest. The cortex waskept moist by the use of warmed (37-40°C) sterile saline throughoutthe entireprocedure.

Injection sites. One monkey received injections into LIP as well as portions of area 7a and area 7b. The other monkeys receivedsmaller injections focused within one of the above-mentioned subregions.The location of each injection site was based on surface landmarksand their known relationship to the cytoarchitectonic bordersof parietal cortex. LIP has been defined as a region in the lateralor posterior bank of the intraparietal sulcus that projects tothe FEF (Andersen et al., 1985). A previous anatomical study confirmedthat LIP occupies a similar location in the Cebus monkey (Tianand Lynch, 1996).

To guide the HSV1 injections visually into the posterior bank of the intraparietal sulcus, in some animals we removed themedial bank of the parietal sulcus using subpial aspiration. Wethen used a 5 µl Hamilton syringe with a 28-32 gauge removableneedle to place multiple injections (0.2 µl per site) of virusinto selected regions of the inferior parietal cortex (see Fig.1). For injections into the intraparietal sulcus, the tip of theneedle was bent at a 90° angle to insure injections were madenormal to the cortical surface. The depth of the injections wasdesigned to place the tip of the syringe needle in cortical layerIV. Injections were spaced 1 mm apart except to avoid blood vessels.The absolute number of injections in each animal varied accordingto the size of the targeted region (see Fig. 1). After each injectioninto the cortex, the needle remained in place for 1-3 min. Whenthe injections were completed, the dura was sutured (if possible),the bone flap was replaced and fixed with sheets of SILASTIC,and the wound was closed in anatomicallayers.

Survival period. After the surgery, animals were placed in a BSL-2 isolation room for further observation and recovery. Observationsof each animal's appearance and behavior were recorded every 4-8hr, or more often as needed. All animals received dexamethasone(0.1-0.5 mg/kg, i.m. or p.o.) during the initial recovery period.Animals that showed signs of discomfort were given butorphenol(0.01-0.4 mg/kg, i.m.) or buprenorphine (Buprenex, 0.01 mg/kg,i.m.). If an animal developed partial or generalized seizures,it was given phenobarbital (2-6 mg/kg, i.m., until the seizureswere controlled; up to 40 mg/kg in a 24 hrperiod).

Virus transport between neurons is time dependent (Zemanick et al., 1991; Strick and Card, 1992; Hoover and Strick, 1999;Middleton and Strick, 2001). Therefore, the number of hours thatan animal survives after an injection determines how many synapseswill be crossed. In the present study, animals were allowed tosurvive for 5-6 d after the virus injections. This time periodpermitted transneuronal transport to second-order but not third-orderneurons (Strick and Card, 1992; Hoover and Strick, 1999; Middletonand Strick, 2001).

At the end of the survival period, each animal was deeply anesthetized (ketamine hydrochloride, 25 mg/kg, i.m.; pentobarbitalsodium, 36-40 mg/kg, i.p.) and transcardially perfused using athree-step procedure (Rosene and Mesulam, 1978). The perfusatesincluded 0.1 M PBS, 4% (w/v) paraformaldehyde in PBS, and 4% paraformaldehydein PBS with 10% (v/v) glycerin. After the perfusion, the brainand cerebellum were photographed, stereotaxically blocked, removedfrom the cranium, and stored in buffered 4% paraformaldehyde with20% glycerin (4°C) for 4-7d.

Histology. Blocks of brain were frozen (Rosene et al., 1986) and serially sectioned in the coronal plane at a thickness of50 µm. Every 10th section was counterstained with cresyl violetfor cytoarchitectonic analysis [E. C. Gower in Mesulam (1982)].To identify neurons labeled by virus transport, we processed free-floatingtissue sections according to the avidin-biotin-peroxidase method(ABC; Vectastain; Vector Laboratories, Burlingame, CA) using acommercially available antibody to HSV1 (Dako, Carpinteria, CA;1:2000 dilution). At least every other section from these animalswas reacted. Sections were mounted onto gelatin-coated glass slides,air dried, and then coverslipped with either Artmount orDPX.

Analytic procedures. Approximately every other section was processed and examined for labeled neurons under bright-field,dark-field, and polarized illumination. Sections through the injectionsites, frontal lobe, superior colliculus, hippocampus, and dentatenucleus were plotted using a computerized charting system (MD2;MN Datametrics, St. Paul, MN). This system uses optical encodersto sense x-y movements of the microscope stage and stores thecoordinates of charted structures (e.g., section outlines, injectionsite zones, and labeled neurons). Digital images of selected structureswere "captured" from the microscope using a video camera coupledto a high-resolution video processing board in a personal computer.Software written in the laboratory enabled us to generate high-resolutioncomposites from multipleimages.

The frequency of plotting varied according to the dimensions of the structure and ranged between 100 and 500 µm intervals.Sections through the superior colliculus were charted while wetand uncoverslipped to take advantage of the differential refractiveindex of myelin compared with neuron cell bodies. This techniqueallowed the layers of the superior colliculus to be clearly visualizedin tissue that had not been subjected to traditional myelin stains,a process that is not compatible withimmunostaining.

Determination of injection sites. Three concentric zones of labeling characterize virus injection sites (Strick and Card,1992; Hoover and Strick, 1999). Zone I contains the needle trackand the highest density of viral staining and pathology. In someinstances, the tissue in this zone disintegrates during tissueprocessing. Zone II contains a dense accumulation of infectedneurons and glia, as well as a high degree of background staining.Zone III contains large numbers of labeled neurons but littleor no background staining. There is evidence that the actual zoneof uptake for transneuronal transport of HSV1 is limited to zoneI [for discussion of this issue, see Strick and Card (1992); Hooverand Strick (1999)].

The combination of subpial aspiration of the medial bank of the parietal sulcus and injection of HSV1 into the lateral bankcaused significant tissue destruction in reacted sections containingthe injection site. Therefore, to aid our determination of thespread of virus at the injection site, we plotted the distributionof first-order labeling in the IPL of the contralateral hemisphereand in the ipsilateral frontal lobe. We identified these regionsof first-order labeling on the basis of the presence of largenumbers of labeled and lysed neurons in the terminal stages ofinfection and intense backgroundstaining.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We made injections of HSV1 into the IPL of four C. apella monkeys. One animal (W06L) received a large injection that includedLIP and portions of areas 7a and 7b. Each of the other animalsreceived more focused injections into either LIP (W17R), area7a (W07L), or area 7b (W21L). We then examined second-order labelingat subcortical sites including the superior colliculus, hippocampus,cerebellum, globus pallidus, and substantia nigra. In the firstsection of our results we will describe the injection sites, inthe second section we will briefly discuss thalamic labeling,and in the third section we will present the patterns of second-orderlabeling.

Characterization of injection sites

The injections of virus in W17R were placed entirely in the lateral (or caudal) bank of the intraparietal sulcus in LIP ofthe Cebus monkey (Tian and Lynch, 1996) (Fig. 1, bottom left).The injections in W07L were placed in area 7a on the corticalsurface, caudal and lateral to LIP (Fig. 1, bottom middle). Theinjections in W21L were placed in the part of area 7b that islocated rostrally in the lateral bank of the intraparietal sulcus(Fig. 1, bottom right). The injections in W06L were placed inthe superficial, middle, and deep thirds of the lateral bank ofthe intraparietal sulcus (data not shown). The intent of the injectionsin W06L was to cover the full medial-lateral and rostrocaudalextent of LIP.

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Figure 1. Schematic diagrams of injection sites. Top left, Lateral view of the hemisphere. Top middle, Enlarged view of the posterior parietal cortex (the region boxed in the top left). The intraparietal sulcus is opened in this diagram. Top right, Flattened map of the intraparietal sulcus. Bottom row, Flattened maps in the region of the intraparietal sulcus showing the targets for injection sites. Each dot represents the target for a single penetration of the injection syringe needle. Bottom left, Animal W17R, the LIP injection site. Bottom middle, Animal W07L, the 7a injection site. Bottom right, Animal W21L, the 7b injection site. All unfolded maps are oriented for display as the left hemisphere to facilitate comparison. Portions of the medial bank of the intraparietal sulcus were aspirated in animals W17R and W21L. Scale bars, 5.0 mm. CS, Central sulcus; IPS, intraparietal sulcus; LS, lunate sulcus; STS, superior temporal sulcus.

As noted in Materials and Methods, we observed significant tissue destruction at the sites of virus injection. To confirmthe placement of injection sites, we examined the distributionof first-order labeling in the contralateral IPL. Callosal projectionsare known to interconnect complimentary regions of the IPL (Divacet al., 1977; Andersen et al., 1985; Neal, 1990; Lewis and VanEssen, 2000), and in W17R, W07L, and W21L, we found dense first-orderlabeling in the contralateral hemisphere at locations that mirroredthe injection sites indicated in Figure 1. The injections in W06Lresulted in first-order labeling not only in contralateral LIPbut also in adjacent portions of area 7a and area7b.

The functional subdivisions of the IPL are known to have unique patterns of connections with the frontal lobe (Andersen etal., 1985, 1990; Cavada and Goldman-Rakic, 1989b; Stanton et al.,1995; Lewis and Van Essen, 2000). Briefly, LIP is known to beinterconnected with the FEF. In fact, this region of posteriorparietal cortex was initially defined by this connection (Seltzerand Pandya, 1980; Barbas and Mesulam, 1981; Andersen et al., 1985).Area 7b is interconnected with the PMv (Cavada and Goldman-Rakic,1989b; Kurata, 1991). Area 7a is interconnected with the supplementaryeye field (SEF) and caudal portions of the cingulate gyrus (CGc)(Andersen et al., 1990), but not with the FEF or the PMv. To characterizethe injection sites further, we examined four areas in the frontallobe for first-order labeling: FEF, PMv, SEF, and CGc. We foundmassive first-order labeling in the "saccadic subregion" of theFEF only in W17R and in W06L. Dense first-order labeling in thePMv of the Cebus monkey (R. P. Dum and P. L. Strick, unpublishedobservations) was present only in W21L and in W06L. Dense first-orderlabeling was present in the SEF and CGc only in W07L and in W06L.On the basis of the labeling in the contralateral IPL and in thefrontal lobe, we will refer to W17R as the "LIP" animal, W07Las the "7a" animal, and W21L as the "7b" animal. We will referto W06L as the "Multi" animal, because the labeling in the contralateralIPL and in the frontal lobe indicates that the injection siteincluded LIP and portions of area 7a and area 7b. Thus, the Multianimal serves as a "second" case for each of the experiments withmore focal injectionsites.

Thalamic labeling

Injections of HSV1 into IPL led to dense labeling in thalamic nuclei known to be the origin of input to each cortical region(Kasdon and Jacobson, 1978; Asanuma et al., 1985; Schmahmann andPandya, 1990; Hardy and Lynch, 1992; Baizer et al., 1993). Labeledneurons were found in other thalamic nuclei as well. This is notsurprising because survival times were set to reveal second-orderneurons. As a consequence, some of the labeled neurons in thethalamus represent second-order neurons labeled by retrogradetransneuronal transport of virus via first-order neurons in corticalareas that innervate the injection site (Hoover and Strick, 1999).

Distribution of second-order labeling

We found second-order neurons, labeled by retrograde transneuronal transport of HSV1, at three major subcortical sites aftervirus injections into the IPL: the superior colliculus, the hippocampus,and the dentate nucleus of the cerebellum. The presence of second-orderneurons at these subcortical sites depended on the portion ofIPL injected (Fig. 2). Specifically, all injection sites thatincluded LIP resulted in second-order neurons in the superiorcolliculus. Injection sites that included area 7a labeled neuronsin the hippocampus, whereas injections that included area 7b labeledneurons in the dentate nucleus of the cerebellum.

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Figure 2. Quantification of second-order labeled neurons. The bar graphs depict the number of labeled neurons in each animal in the superior colliculus (top), hippocampus (middle), and dentate nucleus (bottom). Cell counts are normalized to the highest frequency of sampling (every 100 micrometers).

It is important to note that the three subcortical sites where we found labeled neurons do not project monosynaptically tothe cortical areas under study (Divac et al., 1977; Morecraftet al., 1993). Furthermore, the survival time we used (5-6 d)has been shown in previous studies to label second-order but notthird-order neurons (Zemanick et al., 1991; Strick and Card, 1992;Hoover and Strick, 1999; Middleton and Strick, 2001). Thus, thelabeled neurons in the superior colliculus, hippocampus, and dentatenucleus are termed "second-order" because they have disynapticconnections with the regions injected with HSV1 and are labeledvia retrograde transneuronal transport ofvirus.

Superior colliculus
Most of the second-order neurons labeled in the superior colliculus after virus injections into LIP were found ipsilateralto the injection site. However, unilateral injections of virusalso resulted in a small number of labeled neurons in the contralateralsuperior colliculus. In the LIP animal, almost all of the second-orderneurons were found ipsilaterally in the caudal half of the colliculus.Similarly, most of the second-order neurons were located in thecaudal half of the colliculus in the Multi animal; however a smallportion of the total sample (20%) was found in the rostral halfof the colliculus (Fig. 3, left). On the basis of this differentialdistribution, a topography may exist in the projection from thecolliculus to LIP, although further experiments are necessaryto explore this possibility.

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Figure 3. Distribution of second-order labeled neurons. The histograms show the rostrocaudal distribution of labeling in the superior colliculus for W06L (Multi) versus W17R (LIP) (left), in the hippocampus for W06L (Multi) versus W07L (7a) (middle), and in the dentate nucleus for W06L (Multi) versus W21L (7b) (right).

The laminar distribution of second-order neurons varied with their rostrocaudal location (Fig. 4). Second-order neurons inthe caudal half of the colliculus were located predominantly (91%)in the superficial or visual layers (stratum griseum superficialeand stratum opticum). In contrast, neurons labeled in the rostralhalf of the colliculus were located in both the superficial (59%)and intermediate layers (stratum griseum intermediale; 41%). Avery small number of the second-order neurons also were locatedin the deep layers of the colliculus (e.g., 27/1901 labeled neuronsin the Multi animal).

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Figure 4. Second-order labeling in the superior colliculus after injections including LIP. Top four panels, Plots of sections (section numbers in bottom left corner) through the superior colliculus of W06L. Each black dot indicates one labeled neuron, and dotted lines indicate the borders between layers. A darker dashed line indicates the border between superficial and intermediate layers of the superior colliculus. Bottom panel, The location of labeled cells (in yellow) superimposed on a photomicrograph of the boxed region in the 683 panel. Scale bar, 1.0 mm. SAI, Stratum album intermedium; SAP, stratum album profundum; SGI, stratum griseum intermedium; SGP, stratum griseum profundum; SGS, stratum griseum superficiale; SO, stratum opticum.

Hippocampus
Second-order neurons labeled in the hippocampus after virus injections into area 7a were found primarily ipsilateral to theinjection site, although a small number were found contralaterally.The labeled neurons were found in the pyramidal cell layer ofthe CA1 region. The region of CA1 that contained labeled neuronsoccupied the central third in the transverse plane and primarilythe rostral three-quarters in the longitudinal axis (Fig. 5).The population of labeled neurons in the area 7a animal was centeredslightly caudal to that of the Multi animal (Fig. 3, middle).

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Figure 5. Second-order labeling in the hippocampus after injections including area 7a. Left, Plots of sections (section numbers in bottom right corner) through the hippocampus of W07L. Each black dot indicates one labeled neuron. Right, A photomicrograph of the region outlined in the bottom left section. Scale bar, 500 µm.

Deep cerebellar nuclei
Second-order neurons labeled in the deep cerebellar nuclei after virus injections into area 7b were found in the dentate nucleuscontralateral to the injection site (Fig. 6). Labeled neuronswere located throughout the caudal half of the dentate. The greatestdensity of these neurons was found ventrally in the caudal thirdof the nucleus (Figs. 3, right, 6). The population of labeledneurons in the Multi animal extended more rostrally in the dentatethan did that of the area 7b animal (Fig. 3). The dentate neuronslabeled from virus injections into area 7b had characteristicsthat were typical of "projection" neurons in the deep cerebellarnuclei.

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Figure 6. Second-order labeling in the dentate nucleus after injections including area 7b. Top four panels, Plots of sections (section numbers in bottom left corner) through the dentate nucleus of W21L. Each black dot indicates one labeled neuron. Labeled cells from three consecutive sections spaced 100 µm apart are superimposed on each plot. Bottom panel, Labeled neurons in the dentate of W21L. These neurons were found on section 172. The region enlarged on the bottom left is indicated by the box on the top right. The region enlarged on the bottom right is indicated by the box on the bottom left. Scale bars (bottom panel): top, 1000 µm; bottom left, 500 µm; bottom right, 100 µm. DN, Dentate nucleus; PIP, posterior interpositus.

An additional dense patch of second-order neurons was labeled in a ventral and caudal site within the PIP of the Multi animal.This region of PIP contains neurons with activity related to eyemovements (van Kan et al., 1993; Zhang and Gamlin, 1998). Labeledneurons were not found at this site in the area 7b animal or inany of the other animals of this study. Further experiments arenecessary to determine whether a subregion of LIP, area 7b, oran adjacent region of the IPL such as the ventral intraparietalarea is the source of thislabeling.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We found that IPL is the target of disynaptic output from three subcortical sites: the superior colliculus, the hippocampus,and the cerebellum. In fact, each subcortical region innervatesa different area of the IPL (Fig. 7). LIP receives input fromvisual layers of the superior colliculus, area 7a receives inputfrom the CA1 region of the hippocampus, and area 7b receives inputfrom the dentate nucleus. This discussion will focus on the functionalimplications of these segregated inputs.

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Figure 7. Subcortical inputs to posterior parietal subregions. Each subregion of the posterior parietal cortex that we examined receives input from a different subcortical site. The potential first-order regions that mediate these connections are indicated by asterisks. The diagram also indicates the unique "motor" areas in the frontal lobe that are interconnected with each parietal subregion. The double arrows indicate reciprocal connections. PL, Lateral pulvinar nucleus; PM, medial pulvinar nucleus; VLc, ventral lateral nucleus, pars caudalis.

Superior colliculus to LIP

It is known from experiments with conventional tracers that the superficial, "visual" layers of the superior colliculus projectto the lateral pulvinar nucleus in the thalamus (Harting et al.,1980; Benevento and Standage, 1983). Similarly, a dorsal portionof the lateral pulvinar projects to LIP (Asanuma et al., 1985;Hardy and Lynch, 1992; Baizer et al., 1993). Our results suggestthat neurons in the lateral pulvinar mediate a projection fromthe superficial layers of the superior colliculus to LIP. Neuronsin these layers have visual receptive fields that are retinotopicallyorganized (Lund, 1972; Sparks, 1986). Thus, it is likely thatinput from the colliculus contributes to the visual responsesof LIP neurons (Blatt et al., 1990; Barash et al., 1991a,b).

We found that most of the second-order neurons labeled after LIP injections were located in the caudal portion of the colliculuswhere the peripheral visual field is represented (Cynader andBerman, 1972; Goldberg and Wurtz, 1972a). However, the largerinjection site in LIP labeled some second-order neurons in therostral portion of the colliculus where the fovea is represented.These observations suggest that the projection from the superiorcolliculus to LIP is topographically organized. Furthermore, therough topographic organization of visual receptive fields seenin LIP (Blatt et al., 1990) may be partly a consequence of collicularinput. In this respect, it is interesting that approximately one-quarterof the corticotectal neurons in LIP reported by Paré and Wurtz(1997) respond to foveal stimuli. Similarly, a comparable percentageof tectal input to LIP appears to originate from the rostral (foveal)portion of thecolliculus.

As noted above, our results demonstrate that the superficial layers provide the majority of the collicular input to LIP. Incontrast, the intermediate layers receive the majority of theoutput from LIP (Lynch et al., 1985). Thus, there is a clear "openloop" bias in the flow of information. This pattern of informationflow is evident in the physiological properties of the neuronsin the regions that form this circuit. Certain properties, suchas presaccadic enhancement of visual responses, are present inboth the superficial layers of the colliculus and LIP, but notin the intermediate layers of the colliculus (Goldberg and Wurtz,1972b; Wurtz and Mohler, 1976; Goldberg et al., 1990; Colby etal., 1993). Likewise, sustained delay period activity relatedto an upcoming eye movement is present in both LIP and the intermediatelayers of the colliculus, but not in the superficial layers (Mazzoniet al., 1996; Paré and Wurtz, 1997; Snyder et al., 1997). Thus,our results are consistent with the classical view that the superficiallayers of the colliculus are a source of disynaptic visual inputto LIP and that LIP sends signals related to oculomotor functionback to the intermediate layers (Lynch, 1980, 1992; Lynch et al.,1985; Tian and Lynch, 1996).

In a previous study using similar methods (Lynch et al., 1994), we found that a larger proportion of the collicular inputto FEF originates from the intermediate layers where activityis predominantly related to the generation of saccades (Sparks,1986). Thus, it is likely that the collicular input to FEF isbiased toward oculomotor function, whereas that to LIP is biasedtoward visual processing. On the other hand, a small percentage(<15%) of the cells labeled after LIP injections were found inintermediate layers. Consequently, collicular input to LIP maycontribute to oculomotor function aswell.

Hippocampus to area 7a

Perhaps our most surprising finding is the demonstration that area 7a in the posterior parietal cortex receives a strong disynapticinput from the CA1 region of the hippocampus. The pyramidal cellslabeled in our study were found primarily in the central stripof the CA1 region, in the rostral three-quarters of the hippocampus.The central portion of CA1 projects to area TF of the parahippocampalgyrus (Blatt and Rosene, 1998), and area TF is reciprocally connectedwith area 7a (Andersen et al., 1990). Thus, area TF is likelyto mediate the projection from CA1 to area7a.

Previous studies have shown that CA1 receives direct projections from area 7a (and area 7b) (Cavada and Goldman-Rakic, 1989a;Rockland and Van Hoesen, 1999). There is considerable evidencethat CA1 participates in a spatial memory system useful for navigation(Rolls et al., 1997, 1998; Rolls, 1999). Similarly, area 7a hasbeen implicated in spatial processing. For example, area 7a neuronsdisplay visual responses that are modulated by both head and bodyposition (Snyder et al., 1998). In addition, the responses ofsome area 7a neurons show an interactive dependence on both speedand direction of optic flow (Phinney and Siegel, 2000). This propertymight contribute to the perception of self-motion and headingduring navigation. Thus, input from area 7a to CA1 could influencesome of the spatial properties of CA1neurons.

Our results emphasize a different perspective, namely, that CA1 may contribute to the construction of responses in area 7a.In fact, the CA1 region that sends a disynaptic projection toarea 7a is considerably more extensive than is the CA1 regionthat receives from area 7a. The portion of CA1 that receives directinput from area 7a is located in a small area that is posterior(along the longitudinal axis) and distal (along the transverseaxis) to the large CA1 region that projects to area 7a. Thus,although the hippocampus receives from area 7a and projects toarea 7a, this pathway does not appear to be a simple "closed loop"circuit. Furthermore, the most significant direction of informationflow may be from CA1 to area 7a rather than thereverse.

Human imaging and lesion studies support the concept that a functional linkage exists between the hippocampus and the posteriorparietal cortex (Kesner et al., 1991; Berthoz, 1997). Tasks involvingspatial navigation result in activation of portions of both theposterior parietal cortex and the hippocampus (Maguire et al.,1998; Gron et al., 2000). Similarly, damage to either the hippocampusor posterior parietal cortex leads to difficulty in route finding(Barrash, 1998; Barrash et al., 2000). Our results provide ananatomical substrate for linking these two brain regions intoa parietohippocampal network for spatial navigation. We suggestthat the disynaptic projection from CA1 to area 7a should be viewedas the efferent limb of this circuit. Such a pathway would allowthe memory functions of the hippocampus to influence the spatialprocessing in area7a.

Dentate nucleus to area 7b

The cerebellum is the third subcortical site that we identified as a source of second-order input to IPL. This pathway originatesfrom the dentate nucleus and terminates in a portion of area 7b.It is likely that the dentate projection to area 7b is mediatedprimarily by thalamocortical projections from the caudal portionof VLc. Caudal VLc and some adjacent subdivisions of the ventrolateralthalamus receive dentate input, and these same thalamic subdivisionsproject to regions of the IPL in or near area 7b (see also Sasakiet al., 1976; Kasdon and Jacobson, 1978; Miyata and Sasaki, 1983;Asanuma et al., 1985; Schmahmann and Pandya, 1990).

In previous studies, we found that a number of motor and nonmotor regions in the frontal lobe are the target of dentate output.Neurons that project to each of these cortical areas are clusteredin spatially separate regions of the dentate and form distinct"output channels" (Middleton and Strick, 1994, 1998, 2001). Inthe present study, the dentate neurons that target area 7b arepredominantly located in a ventral region within the caudal thirdof the nucleus. This region is posterior to the dentate outputchannel that innervates M1, and it is nested between the channelsthat project to the hand region of PMv and the saccadic subregionof the FEF (Strick et al., 1993; Lynch et al., 1994; Hoover andStrick, 1999). Thus, the present results suggest that the dentatecontains a distinct output channel that targets a portion of theposterior parietalcortex.

We found that area 7a and LIP receive scant cerebellar input. This suggests that the cerebellum directly influences limitedportions of the IPL. However, we have examined the inputs to arelatively small portion of the posterior parietal cortex. Previouselectrophysiological studies in the monkey have provided evidenceof a projection from the fastigial nucleus to a portion of parietalarea 5 (Sasaki et al., 1976; Miyata and Sasaki, 1983). Similarly,in the cat there appears to be a projection from the dentate andinterpositus to areas 5 and 7 (Wannier et al., 1992; Kakei etal., 1995). Thus, it is likely that the cerebellum gains accessto multiple areas of the posterior parietal cortex, and the completeset of parietal areas that are the target of cerebellar outputremains to bedetermined.

Classically, cerebellar function was thought to be limited to the domain of motor control. A number of recent observationshave led to some alteration in this point of view (Leiner et al.,1986, 1993; Botez et al., 1989; Ivry and Keele, 1989; Schmahmann,1991, 1997a,b; Akshoomoff and Courchesne, 1992; Fiez et al., 1992;Schmahmann and Sherman, 1998). For example, Middleton and Strick(1994, 1998, 2001) have shown that there are output channels inthe dentate that innervate regions of prefrontal cortex. Cerebellarlesions in humans cause cognitive deficits (Grafman et al., 1992;Drepper et al., 1999), and cognitive tasks lead to functionalactivation of cerebellar structures (Petersen et al., 1988; Kimet al., 1994; Raichle et al., 1994; Fiez et al., 1996; Gao etal., 1996; Cabeza and Nyberg, 2000). Our finding that the dentatealso contains an output channel that disynaptically innervatesa subregion of IPL suggests that concepts about cerebellar functionshould be expanded further to include a potential contributionto sensory processing (see also Gao et al., 1996; Ivry, 2000).

At this point, we can only speculate on what the cerebellum might contribute to the function of posterior parietal cortex.However, some important clues may come from the results of recentstudies on the neural basis of prism adaptation. When vision isdisplaced by prisms, systematic errors in reaching movements occur.In addition, the prisms induce a sensory mismatch between thevisual and proprioceptive representations of the limb (see Harris,1965; Welch, 1986). As a consequence, the process of prism adaptationinvolves at least two components, a motor component involvingthe correction of errors in motor output and a perceptual componentinvolving a recalibration of sensory representations. The cerebellumhas long been thought to participate in the motor component ofthis process (Marr, 1969; Oscarsson, 1969; Ito, 1993; Thach, 1998;Baizer et al., 1999). Cerebellar projections to motor areas inthe frontal lobe may represent part of the neural substrate foradapting motor performance. Likewise, the posterior parietal cortexhas been implicated in the perceptual recalibration associatedwith prism adaptation (Clower et al., 1996; Rossetti et al., 1998).We suggest that the cerebellar projection to posterior parietalcortex may provide signals that contribute to (or initiate) thesensory recalibration that occurs during the adaptiveprocess.

  FOOTNOTES

Received Dec. 22, 2000; revised May 9, 2001; accepted May 15, 2001.

This work was supported by the Veterans Affairs Medical Research Service (P.L.S.) and by United States Public Health ServiceGrant MH56661 (P.L.S.) and the Joe Weinberg Research Fund (J.C.L.).We thank M. Page for the development of computer programs andK. Hughes and M. O'Malley-Davis for their expert technical assistance.We also thank Drs. D. I. Bernstein (Children's Hospital MedicalCenter, Cincinnati, OH) and R. D. Dix (Jones Eye Institute, Universityof Arkansas for Medical Sciences, Little Rock, AR) for supplyingHSV1.
D.M.C. and R.A.W. contributed equally to thiswork.

Correspondence should be addressed to Dr. Peter L. Strick, University of Pittsburgh, W1640 Biomedical Science Tower, 200 LothropStreet, Pittsburgh, PA 15261. E-mail: strickp{at}pitt.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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