Transient Changes in Flocculonodular Lobe Protein Kinase C Expression during Vestibular Compensation

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (36)

Citing Articles via Google Scholar

Google Scholar

Articles by Goto, M. M.

Articles by Balaban, C. D.

Search for Related Content

PubMed

PubMed Citation

Articles by Goto, M. M.

Articles by Balaban, C. D.

Pubmed/NCBI databases
Substance via MeSH

Previous Article  |  Next Article

Volume 17, Number 11, Issue of June 1, 1997 pp. 4367-4381
Copyright ©1997 Society for Neuroscience

Transient Changes in Flocculonodular Lobe Protein Kinase C Expression during Vestibular Compensation

Mark M. Goto¹, Guillermo G. Romero², and Carey D. Balaban¹^,³
Departments of ¹ Otolaryngology, ² Pharmacology, and ³ Neurobiology, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania 15213

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Protein kinase C (PKC) is a family of intracellular signal transduction enzymes, comprising isoforms that vary in sensitivityto calcium, arachidonic acid, and diacylglycerol. PKC isoforms $alpha$ , $gamma$ , and $delta$ are expressed by cerebellar Purkinje cells and neuronsin the cerebellar nuclei and vestibular nuclei of the Long-Evansrat. In control rats, these PKCs are distributed symmetricallyin the flocculonodular-lobe Purkinje cells. Behavioral recoveryfrom vestibular dysfunction produced by unilateral labyrinthectomy(UL) is accompanied by asymmetric expression of PKC isoforms inthese regions within 6 hr after UL. These expression changes werelocalized within parasagittal regions of the flocculus and nodulus.The distribution of PKC $alpha$ , - $gamma$ , and - $delta$ were identical, suggestingthat they are coregulated in cerebellar Purkinje cells duringthis early compensatory period. The pattern of Purkinje cell PKCexpression returned to the control, symmetric distribution within24 hr after UL. It is hypothesized that these regional changesin Purkinje cell PKC expression are an early intracellular signalcontributing to vestibular compensation. In particular, regulationof PKC expression may contribute to changes in the efficacy ofcerebellar synaptic plasticity during the acute post-UL period.
Key words: vestibular compensation; protein kinase C; cerebellum; labyrinthectomy; Purkinje cells; signal transduction proteins

INTRODUCTION

Acute vestibular dysfunction produces vertigo, postural asymmetry and instability, nystagmus, tonic eye deviation, and autonomicmanifestations. The resolution of these signs over a period ofdays to weeks is termed vestibular compensation. In the rat, compensationproceeds in three stages: (1) a critical phase (initial 12 hr),characterized by ipsilateral head deviation, spontaneous nystagmus,contralateral limb extension, severe ataxia, and transient boutsof spontaneous circling or rolling; (2) an acute phase (12 hrto several days postinjury), characterized by resolution spontaneousmotor signs; and (3) a compensated phase, characterized by a slightresidual head tilt and occasional ataxic episodes (Llinas andWalton, 1979; Smith and Curthoys, 1989).

Experimental studies implicate the vestibular nuclei, inferior olive and the cerebellar flocculonodular lobe, and posteriorand anterior vermis in vestibular compensation (for review, seeLlinas and Walton, 1979; Smith and Curthoys, 1989). Previous studiesindicate that unilateral labyrinthectomy (UL) in rats producesan immediate asymmetry in neural activity and 2-deoxyglucose (2-DG)uptake in the vestibular nuclei, which resolves within 1 week(Precht et al., 1966; Llinas and Walton, 1979; Patrickson et al.,1985; Luyten et al., 1986). Further, c-fos expression is inducedasymmetrically in the vestibular nuclei within 24 hr of UL inrats (Kaufman et al., 1992; Cirelli et al., 1993). These studiesalso reported increased 2-DG uptake ipsilaterally and decreaseduptake contralaterally in the nodulus within 4 hr of UL in rats(Llinas and Walton, 1979; Patrickson et al., 1985; Luyten et al.,1986), which parallels induced c-fos mRNA expression (Cirelliet al., 1993). An important functional role of these structuresis supported by reports that lesions of the flocculonodular, posterior,and anterior lobes retard vestibular compensation (Jeannerod etal., 1981; Courjon et al., 1982; Igarashi and Ishikawa, 1985),and that compensation is prevented by inferior olive ablationin rats (Llinas and Walton, 1979). Because the inferior olivedefines cerebellar circuitry units via projections to both Purkinjecells zones and targets of those zones in the cerebellar/vestibularnuclei (Balaban, 1984, 1988; Ito 1984), it was hypothesized thataltered expression of intracellular transduction proteins in specificzones may be a biochemical substrate for early stages of vestibularcompensation.

There is little information regarding the role of intracellular signal transduction proteins in the cerebellum or vestibularnuclei during vestibular compensation. Previous studies have implicateda variety of neurotransmitter mechanisms in the process of vestibularcompensation (Ishikawa and Igarashi 1985; Igarashi et al., 1988;Darlington and Smith, 1989, 1992; Darlington et al. 1991; Smithet al., 1991; Calza et al., 1992; Saika et al., 1993). Althoughchanges in c-fos expression (Kaufman et al., 1992; Cirelli etal., 1993) have been reported in the cerebellum during vestibularcompensation, the roles of other intracellular signaling pathwayshave not been eludicated. This study focuses on changes in regionalexpression of protein kinase C (PKC), a family of intracellularsignaling proteins implicated in responses to neurotransmitters,hormones, and growth factors. Recent evidence suggests a roleof PKC in cerebellar long-term depression (Crepel and Krupa, 1988;Linden and Connor, 1995). Because separate isoforms of PKC areaffected differentially by calcium (Ca²⁺), diacylglycerol, and arachidonic acid, PKC may form an importantconduit between second-messenger pathways and cellular responses(Ono et al., 1988; Azizi et al., 1992; Ogita et al., 1992). Thisstudy reports transient, region-specific changes in flocculonodular-lobePKC expression during vestibular compensation.

MATERIALS AND METHODS
Surgical procedures for labyrinthectomies and sham operations. Either UL or sham operations were performed on 250-350 gm maleLong-Evans rats (Charles River Laboratories, Wilmington, MA),with paired sets of sham and control operations performed on thesame day. Rats were anesthetized with Innovar-Vet (fentanyl anddroperidol, 1 ml/kg, i.m.). The bulla was exposed on one sideby blunt dissection via a skin incision near the angle of themandible, and a pediatric otic speculum was placed over the boneto maintain retraction of soft tissues. The ventral surface ofthe bulla was removed with a fine dental burr and microrongeursto expose the middle ear cavity. In the UL group, the base ofthe cochlea was opened with a dental burr and small picks to exposethe vestibule and the otolith organs, and semicircular canal cristaewere ablated with a curette and aspiration. This procedure ablatesthe neuroepithelium, without involvement of the ossicular chain,tympanic membrane, internal acoustic canal, cochlear nerve, facialnerve, or Scarpa's ganglion (Fig. 1). For the sham operations,the bony labyrinth was touched with either a fine burr or a smallcurette. The bulla was sealed with Gelfoam, and the wound wasclosed with sutures. Anesthesia was then reversed by administrationof the opiate antagonist naloxone (0.4 mg/kg, i.m.). The UL ratsdisplayed nystagmus (contralaterally directed quick phases), contralaterallimb extension, and torsion of the head toward the lesioned sidewithin 5 min of naloxone injection. Long-axis rotation ("barrelrotation") was observed rarely within the early acute (1-2 hr)postoperative period.
Fig. 1. Histological verification of unilateral surgical labyrinthectomies. Photomicrographs of horizontal sections through the unoperated(A) and operated (B) ears of case 9311 are shown, with rostraltoward the left. The medial aspect of the section is orientedupward in A and downward in B and C. Note the intact sacculusin A (black arrow) and the complete ablation of the sacculus onthe operated side (B, black arrow). Open arrows show the unaffectedScarpa's ganglia on both the unoperated (A) and operated (B) sides.The Scarpa's ganglion from the operated side is shown at highermagnification in C. Scale bars: A, B, 500 µm; C, 100 µm.
[View Larger Version of this Image (99K GIF file)]

An additional group of five rats was used to characterize the time course of the decline in spontaneous nystagmus after UL.Spontaneous nystagmus was recorded on videotape with a CCD camera(DAGE CCD-72) through an operating microscope under normal roomillumination at 1 hr intervals from 1 to 6 hr, and at 24 and 48hr after the operation. Fast phases of spontaneous nystagmus werecounted in 20 sec periods (3-5 periods/animal/sampling time).The results of least-squares regression analysis [Marquardt-Levenbergalgorithm, using MATLAB (MathWorks, Inc.) function, leastsq.m]indicated that the rate of spontaneous nystagmus can be regardedas a simple exponential decay of form:

(1)

with a time constant ( $tau$ ) of 9 hr and magnitude parameter (A) of 40 beats/20 sec (r = $-$ 0.89). This estimate is consistentwith previous reports that describe the use of short-acting anestheticsin rats. For example, the mean data presented by Kitahara et al.(1995, their Fig. 1) from a study that used mechanical damagefollowed by a 100% ethanol injection in the labyrinth, show atime constant of 17 hr and a magnitude parameter of 28 beats/15sec.

Western immunoblots. Six rats were used for each operative and survival time group for Western blot studies. After a survivaltime of 6 or 48 hr, rats were killed with pentobarbital (100 mg/kg,i.p.). The posterior lobe vermis was dissected rapidly and homogenizedat 4°C in 50 mM Tris buffer, pH 7.5 containing 2 mM EDTA, 1 mMEGTA, 1 mM PMSF, 25 µg/ml leupeptin, 50 µl/ml aprotinin, and 0.33M sucrose. Membrane and soluble fractions were separated by centrifugationat 100,000 g for 30 min. Membrane and soluble fractions were normalizedfor protein content and added to a 200 mM TRIS buffer containing4% SDS, 40% glycerol, 4% $beta$ -mercaptoethanol, and 0.004% bromphenolblue. The samples were boiled for 10 min at 90°C and cooled toroom temperature. Membrane and cytosolic fractions were then loadedin proportionally equivalent amounts on a 9% SDS-PAGE and transferredto a nitrocellulose membrane. Immunodetection was performed usingpolyclonal antibodies recognizing PKC C isoforms $alpha$ , $gamma$ , and $delta$ (LifeTechnologies, Gaithersburg, MD), donkey anti-rabbit horseradishperoxidase-coupled secondary antibody (Jackson ImmunoResearch,West Grove, PA), and an enhanced chemiluminescence detection system(Amersham, Arlington Heights, IL or DuPont/NEN, Boston, MA) exposedto radiographic film (Fuji/Kodak). The intensity of the bandswas determined by densitometry. All comparisons are based on thesedensitometric data.

Immunohistochemical methods. After survival times of 6 hr (sham, n = 8; UL, n = 7 rats), 24 hr (sham, n = 4; UL, n = 4 rats),48 hr (sham, n = 3; UL, n = 4 rats), or 8 d (sham, n = 3; UL,n = 5 rats), Long-Evans rats were killed with a pentobarbitaloverdose (100 mg/kg, i.p.) and perfused transcardially with PBS,followed by a paraformaldehyde-lysine-sodium metaperiodate (PLP)fixative (McLean and Nakane, 1974). The brains were post-fixedfor 2-4 d in 30% sucrose, 4% paraformaldehyde, and then sectionedat 40 µm on a frozen sliding microtome. Before immunohistochemicalprocessing, the sections were stored at $-$ 20°C in a cryoprotectionsolution (300 gm sucrose and 300 ml ethylene glycol in PBS quantumsatis to 1 l).

After rinsing in PBS, sections were incubated in a blocking solution [2% bovine serum albumin (BSA) and 0.1-0.4% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) in PBS] for 4 hr,followed by a 48 hr incubation at 4°C in a solution containinga rabbit polyclonal antibody directed against PKC $alpha$ , PKC $gamma$ , or PKC $delta$ (Life Technologies) diluted 1:1000 in PBS containing 0.1-0.4%CHAPS and 2% BSA. For a nonspecific staining control, anotherset of sections was incubated with a primary rabbit polyclonalantibody directed against PKC $lambda$ (Life Technologies) diluted 1:1000in PBS containing 0.1-0.4% CHAPS and 2% BSA, which produced noimmunohistochemical staining of any cell types in the cerebellum.After rinsing in PBS, the sections were treated for 1 hr at roomtemperature with a solution containing biotinylated goat anti-rabbitIgG (Vector Laboratories, Burlingame, CA) diluted 1:250 in a solutionof 2% BSA in PBS. The antibodies were then visualized by standardABC methods (PBS rinse, incubation in Vectastain Elite ABC reagentfor 1 hr) and a diaminobenzidine chromogen.

Histological verification of surgical labyrinthectomies. After removal of the brains, the perfusion-fixed temporal bones fromthe immunohistochemical studies were dissected from the skull,decalcified in 3 mM EDTA-1.35 N HCl and embedded in paraffin.The temporal bones from half of the UL animals were sectionedserially in the horizontal plane. Every tenth paraffin-embeddedhorizontal section (5-8 µm thickness) was stained with hematoxylinand eosin to verify damage to the neuroepithlium of the semicircularcanal cristae and otolith organ macula and the sparing of Scarpa'sganglion (Fig. 1) by the surgical procedure.

Analysis of pattern of expression in nodulus Purkinje cells. The nodulus distribution of immunopositive Purkinje cells wasanalyzed by constructing flat-mount views of the cortical surfacefrom transverse sections. Images of every transverse section wereacquired on a 486-based computer equipped with a Matrox IP-8/AT(Matrox Electronics Systems, Ltd., Dorval, Quebec, Canada) videoprocessing board running the Optimas package (Version 4.02, Bioscan,Edmonds, WA) from an Olympus BH-2 microscope equipped with a CohuCCD video camera. The Optimas image analysis software was usedto record the distance along the Purkinje layer from midline ofeach immunopositive Purkinje cell in each folium from a set ofevery sixth section. Because climbing fiber inputs and outputsto the vestibular nuclei are ~500 µm-1 mm wide, histograms ofPurkinje cell densities were plotted in 250-µm-wide bins to detectbanding perpendicular long axis of each folium. Microsoft Excelsoftware was used to generate three-dimensional plots of the celldensity data across regions of cerebellar cortex.

Repeated-measures ANOVA was used to test hypotheses regarding regionally specific changes in PKC expression by flocculonodular-lobePurkinje cells. The dependent variable was the total number ofPKC $delta$ -immunopositive nodulus Purkinje cells ipsilateral and contralateralto the operated ear from a set of every sixth section throughthe cerebellum. For the nodulus, these counts were stratifiedfurther by distance from the midline, with separate tabulationsfor a medial region (0-0.5 mm from the midline), an intermediateregion (0.5-1.5 mm lateral to the midline), and a lateral region(>1.5 mm lateral to the midline). Repeated-measures ANOVA [twowithin-group factors: laterality (ipsilateral vs contralateral)and distance from the midline; two between-group factors: treatment(UL vs sham operation) and survival time] and post hoc comparisonswere performed with a standard statistical package (SYSTAT, Evanston,IL) on a PC. The analogous strategy for analysis of patterns offlocculus Purkinje cells is described in detail below.

RESULTS

Western immunoblot analyses
Western immunoblot analyses of PKC isoform expression revealed doublet bands at 74 and 76 kDa representing the two phosphorylationstates of PKC; representative results for PKC $delta$ in the cerebellarvermis are shown in Figure 2. Although individual variations inband density were apparent among sham-operated and unilaterallylabyrinthectomized rats, there were no significant differencesin either the migration distance or the cytosolic versus membrane-boundcomponents of the PKC isoforms as a function of experimental treatment(UL vs sham operation) or survival time (6 or 48 hr). This findingindicates that there is no systematic change in phosphorylationstate or significant post-translational modification of PKCs subsequentto UL. The data did suggest, however, a wide range in baselinePKC expression in the cerebella of both sham and operated rats.Thus, we suggest that (1) immunohistochemical reactions are recognizingthe same proteins in UL and sham-operated rats, and (2) Westernblots are consistent with a wide inter-animal variation in thetotal PKC expression in the cerebellum of the Long-Evans rat.
Fig. 2. Western immunoblot of PKC $delta$ from the cerebellar posterior lobe vermis of 6 hr post-sham-operated (S) and unilateral labyrinthectomy(UL) Long-Evans rats. PKC $delta$ migrates as a 74 and 76 kDa doubletrepresenting its two phosphorylation states. There are no changesin migration distances between sham and UL samples membrane (M)or cytoplasmic (C) fractions. This demonstrates antibody specificityand suggests that the electrophoretic motility of PKC $delta$ does notchange within 6 hr of labyrinthectomy. Reprobing of the blot showedno change in migration distances for PKC $alpha$ or - $gamma$ . Molecular weightmarkers are shown to the left.
[View Larger Version of this Image (41K GIF file)]

PKC immunoreactivity in cerebellar cortex
The cellular distribution of PKC immunoreactive cells in the cerebellum was generally consistent with previous reports onSprague Dawley rats (Chen and Hillman, 1993). The reaction productfor PKC $delta$ was distributed homogeneously within the somata and dendritesof many Purkinje cells (Fig. 3A-C), and in the somata of band-likegroups of presumptive interneurons in the molecular layer (Fig.3A,B, open arrows); the absence of PKC $delta$ -reactive Purkinje cellsin the rostral-most folia of the anterior lobe (Chen and Hillman,1993) was also confirmed. The distribution of immunoreactivityfor PKC $alpha$ was inhomogeneous within Purkinje cells and some molecularlayer interneurons, consisting of a relatively dense perinuclearreaction and lighter somatodendritic immunoreactivity (Fig. 3D).The immunoreactivity for PKC $alpha$ , - $gamma$ , and - $delta$ rarely exceeded backgroundlevels in granule cells. The antibody directed against PKC $lambda$ producedno immunoreactivity in the cerebellum, which served as a controlfor nonspecific staining by the secondary antibody, avidin-peroxidaseconjugate, and diaminobenzidine chromogen.
Fig. 3. Cellular distribution of PKC immunoreactivity in the flocculus (A, C) and nodulus (B, D). A, PKC $delta$ immunoreactivity in theflocculus was observed in somata and dendrites of many Purkinjecells and in somata of some molecular layer interneurons (openarrows). The immunopositive interneurons were observed in bandsalong the ventromedial and ventrolateral margins of the flocculus.Erythrocytes are indicated by small black arrows. B, PKC $delta$ -immunopositivecells are shown in a tangential section through lobule Xa of thenodulus. Note the intense immunoreactivity of Purkinje cell somataand proximal dendrites. Weakly immunopositive molecular layerinterneurons were observed rarely (open arrow). Small black arrowsindicate erythrocytes. C, Higher magnification photomicrographof somatodendritic staining of flocculus Purkinje cells from aband showing no immunopositive molecular layer interneurons. D,High magnification view of PKC $alpha$ immunopositive Purkinje cells(arrows) from a tangential section through the Purkinje cell layerof lobule Xa. Note the intense immunoreactivity associated withthe nuclear region and the weaker reaction in the somata and proximaldendrites.
[View Larger Version of this Image (150K GIF file)]

Nodulus/uvula
Purkinje cells with immunopositive reactions for PKC $alpha$ , - $delta$ , and - $gamma$ isoforms were distributed symmetrically in the flocculonodularlobe of sham-operated rats. Examples of the distribution of PKC $delta$ immunopositive cells are illustrated for the nodulus (Fig. 4)and flocculus (Fig. 8) from rats 6 hr after sham operations. Forthe sham-operated group, ANOVA of the total number of PKC-positivenodulus Purkinje cells ipsilateral and contralateral to the operatedear revealed no significant effect of either survival time (F_(3,14)= 0.732; p > 0.05), laterality (ipsilateral or contralateral tothe operation, F_(1,14) = 3.248; p > 0.05), or the interactionbetween these factors (F_(3,14) = 1.606; p > 0.05). These analysesindicate that PKC-positive Purkinje cells were distributed symmetricallyin the nodulus across survival times (6 hr-8 d) in sham-operatedrats.
Fig. 4. Distribution of PKC $delta$ expression in transverse sections through cerebellar lobules IX (uvula) and X (nodulus) 6 hr postoperatively.These photomicrographs at two comparable levels illustrate resultsfrom lobules IXc and Xa from a sham-operated (case 9330) and aUL (case 9329) rat. Expression in the cerebellar cortex was limitedto Purkinje cell somata and dendrites, but not all Purkinje cellsshowed PKC $delta$ immunoreactivity. Six hours after UL, PKC $delta$ -positivePurkinje cells were distributed in a strikingly asymmetric pattern,with markedly increased expression in an intermediate band inthe nodulus contralateral to the labyrinthectomy (solid arrows).By contrast, 6 hr after a sham operation, Purkinje cells expressingPKC $delta$ were distributed in a more symmetric pattern across the nodulusand uvula, with relatively few immunopositive cells in the intermediateregion. PKC $delta$ -immunoreactivity in the granular layer (asterisks)and interneurons in the molecular layer (open arrows) showed noconsistent patterns across animals. The pattern of PKC $alpha$ and - $gamma$ immunopositive Purkinje cell somata was identical to the distributionof PKC $delta$ immunoreactivity.
[View Larger Version of this Image (83K GIF file)]

Fig. 8. Distribution of PKC $delta$ expression in sections through Long-Evans rat cerebellar flocculus. As in the nodulus and uvula, immunoreactivityis restricted to the Purkinje cells of the cerebellar cortex.The flocculus ipsilateral to the operation is shown on the leftside and the contralateral flocculus is shown on the right sideof the figure. Six hour, post-sham-operated rat flocculi (toppanels) show a variable but consistently symmetric pattern ofPurkinje cell immunoreactivity along the dorsal and ventromedial(b1, demarcated by wide black arrows) surfaces. Six hour, post-ULflocculi (lower panels) show the ventromedial distribution ofexpression as in the sham, with the appearance of bands of expressionalong the lateral crest of the ipsilateral flocculus (b2, openarrows) and the border with paraflocculus (b3, narrow black arrows).The contralateral flocculus shows a broader area of distributionthan ipsilaterally, with expression between areas b1 and b2, andb2 and the lateral margin of b3. Contralaterally, area b3 showsonly a sparse distribution of immunoreactive Purkinje cells. Immunoreactivityfor PKC $alpha$ and - $gamma$ shows an identical distribution.
[View Larger Version of this Image (116K GIF file)]

By contrast, there was a distinct, asymmetric distribution of Purkinje cells expressing the three PKC isoforms across cerebellarlobules Xa (nodulus) and IXc (uvula) within 6 hr after UL (Fig.4 illustrates results for PKC $delta$ ). This result is represented quantitativelyin Figure 5, which compares the patterns of PKC $delta$ -immunoreactivePurkinje cells on flattened surface maps of the Purkinje layerfrom cerebellar lobules VIII-X. The distribution of PKC $alpha$ , PKC $gamma$ -,and PKC- $delta$ -positive Purkinje cells was identical in all UL animals.It was noteworthy that, as suggested by the Western blot analyses,there were inter-animal variations in the total number of PKC-immunopositivePurkinje cells in the nodulus (caudal lobule Xb-lobule Xa) ofboth sham and UL rats. Repeated-measures ANOVA [within-subjectsfactors: laterality (ipsilateral or contralateral to operation)and distance of PKC $delta$ -immunopositive Purkinje cells from the midline(0-0.5 mm, >0.5-1.5 mm, >1.5 mm); between-subjects factors: treatment(UL or sham) and survival time (6, 24, and 48 hr, and 8 d)] andNewman-Keuls tests (Winer, 1971) revealed that there was a transient,asymmetric change in the distribution of PKC-immunopositive Purkinjecells in an intermediate zone of the cerebellar nodulus within6 hr of UL. The results of these analyses are summarized as follows(Figs. 6,7).
Fig. 5. Density histograms of PKC $delta$ immunoreactive Purkinje cells across the rat nodulus and uvula. These data were obtained from everysixth section through these regions. Folia of the nodulus anduvula are indicated along the x-axis. The midline of the cerebellarcortex is indicated with a "0" along the y-axis. Positive distancesrepresent millimeters from the midline contralateral to the sideof operation and negative values the ipsilateral side. The verticalaxis represents immunoreactive Purkinje cell counts in 250 µmincrements. Each histogram represents a different rat; the casenumber is given on each histogram. Density histograms of 6 hrpost-sham-operation show a symmetric distribution of immunoreactivePurkinje cells near the midline that is consistent between ratcerebella and levels of PKC expression. In 6 hr post-UL rat cerebella,the distribution was asymmetric in all rats.
[View Larger Version of this Image (73K GIF file)]

Fig. 6. Zonal changes in lobule Xa (nodulus) PKC $delta$ expression during vestibular compensation. The number of PKC $delta$ -immunopositive Purkinjecells per section from every sixth section through the lobuleXa of the nodulus ipsilateral and contralateral to operationsis plotted as a function of postoperative time. Separate graphsare shown for the entire nodulus (total nodulus, top panels) andfor the intermediate zone (0.5-1 mm lateral to the midline, lowerpanels). Results of repeated-measures ANOVA and post hoc comparisonsare presented in the text. The asterisks indicate a significantelevation in PKC expression on the side contralateral to the operationin the 6 hr UL rats (Newman-Keuls test; p < 0.05 vs ipsilateralside and sham-operated controls at 6 hr).
[View Larger Version of this Image (33K GIF file)]

Fig. 7. Zonal changes in lobule Xa (nodulus) PKC $delta$ expression during vestibular compensation. The number of PKC $delta$ -immunopositive Purkinjecells per section from every sixth section through the lobuleXa of the nodulus ipsilateral and contralateral to operationsis plotted as a function of postoperative time. Separate graphsare shown for the medial nodulus (0-0.5 mm from the midline) andthe lateral nodulus (>1.5 mm from the midline). No significanteffects were observed in the medial nodulus. In the lateral nodulus,there was a bilaterally symmetric increase in the number of PKC-immunopositivePurkinje cells in both sham and UL groups on the eighth postoperativeday (see text).
[View Larger Version of this Image (29K GIF file)]

(1) There is a transient asymmetry in nodulus PKC expression within 6 hr of UL. Analysis of the total number of immunopositivePurkinje cells ipsilateral and contralateral to the operated earrevealed a significant two-way interaction effect for laterality× survival time (F_(3,30) = 4.142; p < 0.05) and a significantthree-way interaction for laterality × survival time × operationtype (F_(3,30) = 7.956; p < 0.01). These significant interactioneffects can be attributed strictly to the 6 hr survival time,which displayed a highly significant main effect for laterality(F_(1,13) = 13.352; p < 0.01) and laterality × operation-type interactioneffect (F_(1,13) = 16.203; p < 0.01); no significant effects werepresent for either 24 or 48 hr, or 8 d survival groups. Newman-Keulstests of the data from the 6 hr survival groups demonstrated thatthese significant interaction effects reflected a significantincrease in the number of immunopositive cells contralateral tothe lesion (p < 0.01) versus the side ipsilateral to the lesionand both sides of the sham-operated controls.

(2) The transient asymmetry in nodulus PKC expression within 6 hr of UL is restricted to an intermedate zone 0.5-1.5 mm lateralto the midline. ANOVA of the Purkinje cell distribution by sagittalzone indicated that significant changes in the symmetry of Purkinjecell PKC expression were restricted to an intermediate zone (between0.5 and 1.5 mm from the midline) of the nodulus. Significant two-waylaterality × survival time (F_(3,30) = 2.977; p < 0.05) and three-waylaterality × survival time × operation type (F_(3,30) = 9.267;p < 0.01) were present only for the Purkinje cells in this intermediateregion (Fig. 6); these interaction effects were not significantfor the distribution of immunopositive Purkinje cells in eithermedial (0-0.5 mm from the midline) or lateral (>1.5 mm from themidline) nodulus zones (Fig. 7). When the data from each survivaltime were analyzed separately, only the intermediate zone (0.5-1.5mm lateral to the midline) from the 6 hr survival groups revealedeither a significant main effect of laterality (F_(1,13) = 10.896;p < 0.01) and a significant laterality × operation-type interactioneffect (F_(1,13) = 18.622; p < 0.01). These effects were absentfor other survival times and other nodulus zones.

(3) The change in nodulus intermediate-zone PKC expression reflects a transient increase in the number of immunopositive Purkinjecells contralateral to the lesion within 6 hr of UL. Newman-Keulscomparisons of the cell counts in the intermediate zone in the6 hr UL and sham groups indicated that three findings producedthe significant interaction effects in ANOVA. First, there wasno significant difference between the two sides of the sham-operatedanimals. Second, there was a highly significant increase in thenumber of PKC-positive neurons contralateral to the UL, comparedwith either the side ipsilateral to the UL or with either sideof the sham-operated animals (p < 0.01). Finally, there was nosignificant difference between the number of PKC-positive Purkinjecells on the side ipsilateral to the UL and either side of thesham-operated group. As described above, the symmetric distributionwas restored within 24 hr of UL.

A second zonal effect on PKC expression was observed symmetrically in the lateral zone (>1.5 mm from the midline) of the nodulus(Fig. 7). ANOVA revealed a significant effect of survival timeon the number of immunopositive Purkinje cells in this region(F_(3,30) = 4.602; p < 0.01), which reflected a parallel, symmetricincrease in expression in both the UL and sham-operated 8 d survivalgroups. Because it was identical in both sham-operated controland UL rats, this regional increase in expression is likely toreflect features of recovery from surgical trauma (and anesthesia)that are unrelated to vestibular compensation.

Flocculus
Within 6 hr after UL, a characteristic asymmetric distribution of PKC $alpha$ , - $delta$ , and - $gamma$ expression was observed in the ipsilateraland contralateral cerebellar flocculus. The distribution of immunoreactiveflocculus Purkinje cells after UL was virtually identical forthe three PKC isoforms examined. Figure 8 compares the distributionof PKC $delta$ in transverse sections through the middle of the ipsilateraland contralateral flocculi of 6 hr sham-operated and UL rats.Figure 9 shows the distribution of PKC $gamma$ -immunoreactive Purkinjecell somata in a series of transverse sections through the ipsilateraland contralateral flocculi of a 6 hr UL rat. In the sham-operatedrats (Fig. 8), immunoreactive Purkinje cells were distributedsymmetrically in the ipsilateral and contralateral flocculi, wherethey spanned the dorsal surface of the flocculus and the medialthird of the ventral surface. By contrast, immunoreactive Purkinjecells were distributed asymmetrically in the ipsilateral and contralateralflocculi within 6 hr of UL in patterns that differed from thesham-operated rats. Both the intensity of immunoreactivity andthe number of immunopositive Purkinje cells were greater qualitativelyon the side contralateral to the labyrinthectomy (Fig. 9). Repeated-measuresANOVA confirmed that there is a statistically significant, transientincrease in the number of PKC-immunoreactive Purkinje cells (PKC $delta$ )in the flocculus contralateral to the unilateral labyrinthectomy,and that there were no concurrent changes in the number of PKC-immunopositivePurkinje cells in either the flocculus of the sham-operated ratsor the ventral paraflocculus (Fig. 10). The results of these analysesare summarized as follows.
Fig. 9. Rostrocaudal distribution of PKC $gamma$ expression in the Long-Evans rat flocculus. The symmetric banding along the dorsal and ventromedial(b1, demarcated by wide black arrows) floccular surfaces in the6 hr sham-operated rat runs caudorostrally. In the 6 hr post-ULflocculi, the broader contralateral banding between b1 and b2(demarcated by open arrows), and b2 and the lateral margin ofb3 (demarcated by narrow black arrows) runs to merge on the dorsalsurface of the rostral pole. The sparser band of immunoreactivityin contralateral b3 also runs caudorostrally. PKC $alpha$ and - $delta$ showthe same distribution of expression.
[View Larger Version of this Image (137K GIF file)]

Fig. 10. Changes in flocculus and ventral paraflocculus Purkinje cell PKC $delta$ expression. The number of PKC $delta$ -immunopositive Purkinje cellsper section (from every sixth section through the flocculus andventral paraflocculus) ipsilateral and contralateral to operationsis plotted as a function of postoperative time. Separate graphsare shown for the total flocculus (top panels) and ventral paraflocculus.In the flocculus, there was a statistically significant increasein PKC expression contralateral to the lesion in the 6 hr UL group(Newman-Keuls test; p < 0.01 compared with the ipsilateral sideand both sides of the 6 hr sham-operated group). No significanteffects were observed in the ventral paraflocculus.
[View Larger Version of this Image (32K GIF file)]

(1) There is a transient asymmetry in flocculus PKC expression 6 hr after UL. Analysis of the total number of immunopositivePurkinje cells ipsilateral and contralateral to the operated earrevealed a significant two-way interaction effect for laterality× survival time (F_(2,18) = 3.92; p < 0.05) and a significant three-wayinteraction for laterality × survival time × operation type (F_(2,18)= 3.597; p < 0.05). These significant interaction effects canbe attributed strictly to the 6 hr survival groups, in which analysesof the UL and sham-operated groups displayed a highly significantmain effect for laterality (F_(1,9) = 13.07; p < 0.01) and laterality× operation-type interaction effect (F_(1,9) = 21.21; p < 0.01);no significant effects were present for either 24 or 48 hr survivalgroups. Newman-Keuls tests (based on the mean squared error termfor the interaction effects; Winer, 1971) demonstrated that thesesignificant interaction effects in the 6 hr UL group reflecteda significant increase in the number of immunopositive cells contralateralto the lesion (p < 0.01) versus the side ipsilateral to the lesionand both sides of the sham-operated controls; there was no significantdifference among the latter three regions.

(2) There were no significant differences as a function of either laterality or operation type at other survival times.

(3) No significant effects of laterality, operation type, or survival time were present in the ventral paraflocculus.

Both qualitative observations (Figs. 8,9) and quantitative analyses (Fig. 11) indicated that the transient changes in flocculusPKC expression were not distributed uniformly within the flocculus.On the side ipsilateral to the lesion, the distribution of PKC-positivePurkinje cell somata on the ventral surface of the flocculus wasvirtually identical to that of the sham-operated rats, occupyinga band along the ventromedial margin of the flocculus (b1). Incontrast to the continuous distribution of PKC-positive Purkinjecells on the dorsal and lateral aspects of the flocculus in thesham-operated animals, however, the UL animals displayed two bandsof labeled Purkinje cells in the ipsilateral flocculus, one alongthe lateral crest of the flocculus (b2), and the other along itsborder with the ventral paraflocculus (b3). These bands seemedto merge on the dorsal surface of the rostral pole of the flocculus.The contralateral flocculus in the UL rats, however, also displayedimmunoreactive Purkinje cells over a broader area of the flocculus,including both the regions designated b1 and b2 on the ipsilateralside, and including most of the area between b1 and b2 and betweenb2 and the lateral margin of b3. By contrast, the region labeledb3 on the ipsilateral side contained only a sparse populationof immunoreactive Purkinje cells contralaterally. The identicalpattern appeared for PKC $delta$ , - $gamma$ , and - $alpha$ . Within 24 hr after surgicalprocedures, no differences were detected in the symmetric distributionsof PKC-positive Purkinje cells in flocculi of sham-operated andUL rats.
Fig. 11. Transient regional changes in flocculus Purkinje cell expression of PKC $delta$ . The number of PKC $delta$ -immunopositive Purkinje cellsper section from every sixth section through the intermediateaspect of flocculus is plotted as a function of postoperativetime. Increased expression was observed contralaterally 6 hr afterUL (Newman-Keuls test; p < 0.01) in region 1, which included theentire ventral surface and intermediate third of the dorsal surfaceof the nodulus. No significant effects were observed in region2, the lateral and medial thirds of the dorsal surface of theflocculus.
[View Larger Version of this Image (31K GIF file)]

These qualitative observations were confirmed by quantitative analyses. On the basis of the zonal organization of olivoflocculusprojections described by Ruigrok et al. (1992), the flocculusand ventral paraflocculus were divided into three rostrocaudalregions: (1) caudal (25%), which receives climbing fiber inputpredominantly from the rostral pole of the medial accessory oliveand the ventrolateral outgrowth of the principal olive; (2) rostral(25%), which receives climbing fiber input predominantly fromthe ventrolateral outgrowth and ventral leaf of the principalolive (with a small contribution at the rostral pole of the flocculusfrom the dorsal cap); and (3) the intermediate flocculus (central50%), which receives climbing fiber inputs predominantly fromthe dorsal cap (with a projection from the ventral leaf of theprincipal olive to the lateral aspect of the ventral paraflocculus).Transverse sections at each level were then divided into eightregions for further analysis: (1) medial third of the ventralsurface of the flocculus (corresponding to region b1 in Figs.7,8), (2) intermediate aspect of the ventral surface (extendingto a line perpendicular to the mediolateral axis of the flocculuswhite matter at the lateral margin of the white matter), (3) lateralaspect of the ventral folium (extending to the lateral crest ofthe flocculus), (4) lateral aspect of the dorsal folium, (5) intermediateaspect of the dorsal folium, (6) medial aspect of the dorsal flocculusfolium (ending in the center of the posterolateral fissure), (7)medial half of the ventral paraflocculus, and (8) lateral halfof the ventral paraflocculus. Repeated-measures ANOVA of the numberof PKC $delta$ -immunopositive cells per section revealed that there wastransient, regionally specific change in expression in the flocculus(Fig. 11).

(1) The asymmetry in the number of PKC-immunopositive flocculus Purkinje cells 6 hr of UL is not distributed uniformly withinthe Purkinje cell layer. ANOVA of the number of immunoreactivePurkinje cells in each flocculus region (regions 1-6 above) fromthe 6 hr labyrinthectomy and sham-operated groups revealed a significantmain effect of laterality (F_(1,5) = 7.08; p < 0.05) and threesignificant interaction effects that suggest that effects varyas a function of the operation type, rostrocaudal level, and regionwithin each level: (a) laterality × operation-type interaction(F_(1,5) = 8.471; p < 0.05), which indicates that the lateralityeffect varies with operation type; (b) rostrocaudal level × regioninteraction effect (F_(8,40) = 2.9, p < 0.05), which indicatesthat the the number of immunopositive Purkinje cells in each regionvaries with the rostrocaudal level of the sections; (c) laterality× operation type × rostrocaudal level × region interaction (F_(8,40)= 2.49; p < 0.05), which is consistent with laterality effectsrestricted to particular operation type, rostrocaudal levels,and regions of the flocculus.

(2) The asymmetry in PKC expression appeared only at intermediate levels of the flocculus. Repeated-measures ANOVA for datafrom each rostrocaudal level revealed that only intermediate levelsof the flocculus displayed either a significant main effect oflaterality (F_(1,9) = 15.98; p < 0.01) or a significant laterality× operation-type interaction effect (F_(1,9) = 9.67; p < 0.05).These results reflected two findings at intermediate levels ofthe flocculus: a highly significant elevation in the number ofimmunoreactive Purkinje cells contralateral to the operated earin the unilateral labyrinthectomy group (F_(1,5) = 28.6; p < 0.01)and no significant asymmetry in the distribution of immunopositivePurkinje cells in the sham-operated group (F_(1,4) = 0.35; NS).

(3) The asymmetric distribution PKC-immunopositive Purkinje cells at intermediate levels of the flocculus was transient inUL rats. Separate analyses were used for data at each survivaltime to test the hypothesis that the asymmetric distribution ofPKC-positive Purkinje cells at intermediate flocculus levels inUL rats was restricted to the 6 hr group. Repeated-measures ANOVAof data from rats 24 and 48 hr after the operation showed no significantmain effects of either the type of operation (UL or sham) or laterality(ipsilateral or contralateral to the operation). The interactioneffect was also not significant at either time.

(4) Six hours after UL, the number of PKC-immunopositive Purkinje cells is increased in a region spanning the ventral surfaceand intermediate third of the dorsal surface of the flocculus.Repeated-measures ANOVA indicated that the significant lateralityeffect 6 hr after UL reflected an increase in the number of PKC-immunopositivePurkinje cells along the ventral surface and the intermediatethird of the dorsal surface of the flocculus (F_(1,5) = 24.10;p < 0.01), with no significant difference between the ipsilateraland contralateral sides in medial and lateral aspects of the dorsalsurface of the flocculus (F_(1,5) = 1.43; NS). For further analysis,the former region was termed region 1 and the latter area region2. In the 6 hr sham-operated group, there were no significantlaterality effects in either region 1 (F_(1,4) = 0.31; NS) or region2 (F_(1,4) = 0.29; NS).

(5) The asymmetric expression of PKC in region 1 of intermediate levels of the flocculus is transient. The number of PKC $delta$ -immunopositivePurkinje cells per section in region 1 (ventral surface and intermediateaspect of the dorsal surface) and region 2 (lateral and medialaspects of the dorsal surface) of the flocculus were used as dependentvariables to test the hypothesis that the changes in region 1PKC expression are transient. Repeated-measures ANOVA of the region1 data from both operation types and three survival times revealeda significant main effect of laterality (F_(1,18) = 5.799; p <0.05), a significant laterality × survival time interaction (F_(2,18)= 4.327; p < 0.05) and a marginal three-way laterality × survivaltime × operation type (F_(3,18) = 3.526; p = 0.051) interactioneffect. Two lines of evidence indicated that these effects inregion 1 can be attributed to the transient increase in PKC expressioncontralateral to the lesion in the 6 hr UL group. First, separateanalysis of the UL groups revealed a significant main effect oflaterality (F_(1,10) = 6.39; p < 0.05) and a significant laterality× survival time interaction effect (F_(2,10) = 6.09; p < 0.05).No significant main effects (laterality, survival time) or interactioneffects were observed in parallel analyses of the sham-operatedrats. Second, in separate comparisons of the effects of operationtype at each survival time, a significant main effect of laterality(F_(1,9) = 18.72; p < 0.01) and laterality × operation-type interactioneffect (F_(1,9) = 11.80; p < 0.01) were present in analyses forthe 6 hr postoperative groups. No significant main effects (operationtype, laterality) or interactions were observed at the other survivaltimes. There were no significant main effects or interaction effectsin parallel analyses of region 2.

(6) No significant effects of laterality, operation type, or survival time were present in the ventral paraflocculus at intermediatelevels.

Thus, the data indicate that there is a transient increase in the number of PKC-immunopositive Purkinje cells in an intermediateregion of the flocculus within 6 hr after UL, which resolves within24 hr after the operation. No corresponding changes are observedin other regions of the flocculus in UL rats or in sham-operatedcontrols.

DISCUSSION
This study has demonstrated transient changes in the distribution of PKC-positive flocculonodular-lobe Purkinje cells afterunilateral labyrinthectomy. Regionally selective increases inPKC-immunopositive flocculonodular-lobe Purkinje cells were observedcontralateral to the lesioned ear within 6 hr after labyrinthectomy,and this change reverted to a symmetric distribution within 24hr after labyrinthectomy. These changes in PKC expression arecorrelated temporally with early behavioral manifestations ofvestibular compensation and changes in electrophysiological andmetabolic activity of neurons in central vestibular pathways.Because the time constant for the disappearance of spontaneousnystagmus is 9 hr in UL rats under these experimental conditions(see Materials and Methods), these cerebellar PKC expression changesare concurrent with the period of resolution of spontaneous nystagmus.Electrophysiological and 2-DG utilization evidence indicates thatUL results in an immediate asymmetry in activity and glucose consumptionin the vestibular nuclei, which resolves to symmetric activityduring the first postoperative week (Precht et al., 1966; Llinasand Walton, 1979; Patrickson et al., 1985; Luyten et al., 1986).Although data on zonal distribution of 2-DG utilization have notbeen reported, the changes in PKC expression are opposite thepattern of 2-DG utilization during the acute post-UL period (4-6hr postoperative): nodulus PKC expression increases and 2-DG uptakedecreases contralateral to UL (Patrickson et al., 1985), whereasPKC expression is reduced and 2-DG uptake increased ipsilateralto the lesion. It is unclear whether the PKC changes are responsesto metabolic or activity changes, a cause of these changes, oran unrelated, temporally coincident phenomenon. It is importantto note, however, that the demonstration of transient, lateralizedchanges in Purkinje cell PKC expression implies that both asymmetricand bilaterally symmetric patterns of PKC expression may be producedby a common set of underlying processes.

Changes in PKC expression patterns displayed three features. First, there was a transient increase in the number of PKC-immunopositivePurkinje cells in the intermediate zone of the nodulus and region1 at intermediate levels of the flocculus on the side contralateralto peripheral vestibular damage within 6 hr of UL. This responsereverted to bilateral symmetry (the sham-operated control pattern)within 24 hr after UL. Second, the number and distribution ofPKC-immunopositive Purkinje cells were localized to specific regionswithin the flocculonodular lobe. In addition to the spatiallyrestricted, early increase in PKC-immunopositive Purkinje cellsin the contralateral flocculonodular lobe, a symmetric increasein PKC expression was observed in the lateral zone of the nodulusin both UL and sham-operated groups on postoperative day 8. Finally,the transient changes in PKC expression were absent in other cerebellarregions (e.g., ventral paraflocculus, posterior lobe vermis, anteriorlobe, and cerebellar hemispheres). Because Purkinje cells do notreceive direct, primary vestibular afferents, it is highly unlikelythat the 6 hr post-UL effects are a direct response to an injuredor degenerating primary afferents.

Several neural mechanisms may potentially contribute to regionally specific, transient changes in Purkinje cell PKC expressionduring the first 6 hr after UL (Fig. 12). The prominent parasagittalcomponent of flocculonodular-lobe PKC expression changes suggeststhe hypothesis that dynamic regulation of Purkinje cell PKC expressionis mediated by parasagittal neural circuitry components. Anatomicand physiological evidence has revealed two major parasagittalcomponents of flocculonodular lobe Purkinje cell circuitry: climbingfiber projections and efferent projections from Purkinje cellsto the vestibular nuclei (Brodal and Kawamura, 1980; Balaban,1984, 1988; Ito, 1984). The relatively rapid, post-UL changesin flocculus PKC expression are centered in the portion of theolivary projection zone termed FE, which receives input from thecaudal dorsal cap (Ruigrok et al., 1992). It is notable that PKCexpression changes were absent in the adjacent ventral paraflocculus,which contains the part of zone FE that receives input from therostral dorsal cap. Anatomical evidence from the rat (Bernard,1987) and rabbit (Balaban and Henry, 1988; Katayama and Nisimaru,1988; Tan et al., 1995) suggests that the intermediate part ofthe nodulus receives climbing fiber input predominantly from thedorsal cap and ventrolateral outgrowth. Dorsal cap neurons areactivated by the retinal slip stimulation (Leonard et al., 1988),implying that early changes in flocculonodular-lobe PKC expressionmay represent local intracellular responses to changes in climbingfiber activity that reflect spontaneous nystagmus during the initialhours after UL. The asymmetry of the PKC response may reflectmonocular, directionally selective visual inputs to caudal dorsalcap neurons, which respond with excitation during temporal-to-nasalhorizontal retinal slip stimulation and with inhibition to nasal-to-temporalstimulation of the contralateral eye (Leonard et al., 1988). Becauseclimbing fiber projections are crossed, retinal slip during slowphases of spontaneous nystagmus would produce an excitatory responsein caudal dorsal cap climbing fibers within the ipsilateral flocculonodularlobe and an inhibitory response in climbing fibers innervatingthe contralateral flocculonodular lobe. This line of reasoningimplies that PKC upregulation may reflect decreased climbing fiberactivity. The potential role of climbing fibers in regulationof PKC expression parallels the apparent transsynaptic regulationof Purkinje cell expression of Ca²⁺/calmodulin-dependent cyclic nucleotide phosphodiesterase by climbingfibers (Balaban et al., 1989).
Fig. 12. Schematic diagram of neural circuits that may influence PKC expression during vestibular compensation. Two potential substratesfor the parasagittal distribution of increased PKC expressionin the flocculonodular lobe are (1) an anterograde influence ofclimbing fiber projections from the dorsal cap and ventrolateraloutgrowth and (2) a retrograde influence via zonal projectionsof Purkinje cells to the vestibular nuclei. A contribution ofmossy fiber-granule cell-parallel fiber and monoaminergic projections,however, cannot be excluded.
[View Larger Version of this Image (25K GIF file)]

The second parasagittal component of flocculonodular lobe circuits is defined by zonal efferent projections to the ipsilateralvestibular nuclei. The early PKC changes in the flocculus arecentered in a zone that projects to the medial vestibular nucleus(Balaban, 1984; Ito, 1984), whereas the intermediate nodulus projectsto the superior and medial vestibular nuclei (Balaban, 1984; Shojakuet al., 1987). Electrophysiological studies of medial vestibularnucleus neurons after acute labyrinthectomy have reported reducedresting activity ipsilateral and increased resting activity contralateralto the lesion (for review, Smith and Curthoys, 1989). A similarpattern of 2-DG uptake has been reported within a few hours oflabyrinthine damage, with increased uptake in the contralateralmedial vestibular nucleus (Patrickson et al., 1985) and decreaseduptake ipsilaterally (Llinas et al., 1979; Patrickson et al.,1985; Luyten et al., 1986). Given the existence of presynapticreceptors and retrograde transport mechanisms, it is possiblethat the sagittal distribution of changes in Purkinje cell PKCexpression reflects a retrograde influence of vestibular nucleusactivity such that elevated activity in the contralateral vestibularnuclei induces an upregulation of PKC expression in presynapticPurkinje cells. Because the asymmetric changes in PKC expressiondid not seem to be uniform within an entire parasagittal bandin the flocculus or nodulus, however, a contribution of mossyfiber-granule cell-parallel fiber pathways, monoaminergic afferents,or intracerebellar interneurons to these responses cannot be excluded.

It is noteworthy that transient, asymmetric changes in Purkinje cell PKC $alpha$ , - $delta$ , and - $gamma$ expression were distributed within sagittalregions of the flocculonodular lobe, a region related to controlof vestibulo-ocular reflexes, but were absent in the anteriorvermis, a region related to postural control. Previous studieshave reported that lesions of the flocculonodular lobe producespontaneous nystagmus and impair compensation of the symmetryof vestibulo-ocular reflexes after UL (Llinas and Walton, 1979;Jeannerod et al., 1981; Courjon et al., 1982; Igarashi and Ishikawa,1985; Smith and Curthoys, 1989). The location of changes in Purkinjecell PKC expression suggests further that these intracellularsignal transduction substrates are regulated within distinct cerebellarcircuits that influence vestibular reflexes. For example, thezonal asymmetries in flocculus PKC expression 6 hr after UL suggestan association with a region that receives horizontal retinalslip-climbing fiber input, projects to the medial vestibular nucleus,and modulates horizontal vestibulo-ocular reflexes (Ito, 1985;Leonard et al., 1988). In the cerebellum, PKC seems to be an importantmediator of long-term depression of parallel fiber EPSPs by climbing-fiberactivation (Linden and Connor, 1995). Of particular importanceis the observation that PKC activation both depresses parallelfiber EPSPs (Crepel and Krupa, 1988; Boxall et al., 1995) andoccludes the production of long-term depression of parallel-fiberEPSPs by climbing fiber activation (Boxall et al., 1995). Althoughlong-term depression of Purkinje cell responses was reported inmutant mice deficient in PKC $gamma$ , the significant reduction in thisresponse by intracellular injections of a PKC inhibitor (Chenet al., 1995) is consistent with a role of multiple PKC isoformsin the induction of long-term depression. The observation of parallelchanges in Purkinje cell expression of calcium-sensitive (PKC $alpha$ and - $gamma$ ) and calcium-insensitive (PKC $delta$ ) forms of PKC within 6 hrof labyrinthectomy is consistent with this perspective. Thus,regional changes in Purkinje cell PKC expression may be an earlyintracellular signal contributing to vestibular compensation.It is suggested that regulation of PKC expression may facilitatesynaptic plasticity by adjusting the efficacy of biochemical responsesof Purkinje cells to intracellular fluxes in calcium, arachidonicacid, and diacylglycerol during the acute post-UL period.

FOOTNOTES

Received Jan. 16, 1997; revised March 4, 1997; accepted March 7, 1997.

This work was supported by National Institutes of Health (National Institute on Deafness and Other Communication Disorders)Grant R01 DC02556 (C.D.B.), a Howard Hughes Medical InstituteMedical Student Research Training Fellowship (M.M.G.), and TheWilliam Randolph Hearst Otological Research Fellowship, DeafnessResearch Foundation (M.M.G.). We thank Gloria Limetti, Maria Freilino,and Steve Slezak for expert technical and histological assistance.

Correspondence should be addressed to Dr. Carey D. Balaban, Department of Otolaryngology, University of Pittsburgh, The Eyeand Ear Institute of Pittsburgh, 203 Lothrop Street, Pittsburgh,PA 15213.

Dr. Goto's present address: Department of Otolaryngology, Naval Medical Center-San Diego, 34800 Bob Wilson Drive, San Diego,CA 92134-5000.

REFERENCES

Azzi A, Boscoboinik D, Hensey C (1992) The protein kinase C family. Eur J Biochem 208:547-557[Web of Science][Medline].
Balaban CD (1984) Olivovestibular and cerebellovestibular connections in albino rabbits. Neuroscience 12:129-149[Web of Science][Medline].
Balaban CD (1988) Distribution of inferior olivary projections to the vestibular nuclei of albino rabbits. Neuroscience 24:119-134[Web of Science][Medline].
Balaban CD, Henry RT (1988) Zonal organization of olivo-nodulus projections in albino rabbits. Neurosci Res 5:409-423[Web of Science][Medline].
Balaban CD, Billingsley ML, Kincaid RL (1989) Evidence for transsynaptic regulation of calmodulin-dependent cyclic nucleotide phosphodiesterase in cerebellar Purkinje cells. J Neurosci 9:2374-2381[Abstract].
Barmack NH, Fagerson M, Fredette BJ, Mugnaini E, Shojaku H (1993a) Activity of neurons in the beta nucleus of the inferior olive of the rabbit evoked by natural vestibular stimulation. Exp Brain Res 94:203-215[Web of Science][Medline].
Barmack NH, Fagerson M, Errico P (1993b) Cholinergic projection of the dorsal cap of the inferior olive of the rat, rabbit and monkey. J Comp Neurol 328:263-281[Web of Science][Medline].
Bernard JF (1987) Topographical organization of olivocerebellar and corticonuclear connections in the rat: a WGA-HRP study: I. Lobules IX, X, and the flocculus. J Comp Neurol 263:241-258[Web of Science][Medline].
Boxall AR, Lancaster B, Garthwaite J (1966) Tyrosine kinase is required for long-term depression in the cerebellum. Neuron 16:805-813.
Brodal A, Kawamura K (1980) In: Olivocerebellar projection: a review. Berlin: Springer.
Calza L, Giardino L, Zanni M, Galetti G (1992) Muscarinic and gamma-aminobutyric acid-ergic receptor changes during vestibular compensation: a quantitative autoradiographic study of the vestibular nuclei complex in the rat. Eur Arch Otorhinolaryngol 249:34-39[Medline].
Chen C, Kano M, Abeliovitch A, Chen L, Bao S, Kim JJ, Hashimoto K, Thompson RF, Tonegawa S (1995) Impaired motor coordination correlates with presistent multiple climbing fiber innervation in PKC $gamma$ mutant mice. Cell 83:1233-1242[Web of Science][Medline].
Chen S, Hillman DE (1993) Compartmentalization of the cerebellar cortex by protein kinase C delta. Neuroscience 56:177-188[Web of Science][Medline].
Cirelli C, Pompeiano M, D'Ascanio P, Pompeiano O (1993) Early C-fos expression in the rat vestibular and olivocerebellar systems after unilateral labyrinthectomy. Arch Ital Biol 131:71-74[Web of Science][Medline].
Courjon JH, Flandrin JM, Jeannerod M, Schmid R (1982) The role of the flocculus in vestibular compensation after hemilabyrinthectomy. Brain Res 239:251-257[Web of Science][Medline].
Crepel F, Krupa M (1988) Activation of protein kinase C induces a long-term depression of glutamate sensitivity of cerebellar Purkinje cells: an in vitro study. Brain Res 458:397-401[Web of Science][Medline].
Darlington CL, Smith PF (1989) The effects of N-methyl-D-aspartate antagonists on the development of vestibular compensation in the guinea pig. Eur J Pharmacol 174:273-278[Web of Science][Medline].
Darlington CL, Smith PF (1992) Pre-treatment with a Ca²⁺ channel antagonist facilitates vestibular compensation. NeuroReport 3:143-145[Web of Science][Medline].
Darlington CL, Flohr H, Smith PF (1991) Molecular mechanisms of brainstem plasticity: the vestibular compensation model. Mol Neurobiol 5:355-368[Web of Science][Medline].
Igarashi M, Ishikawa K (1985) Post-labyrinthectomy balance compensation with preplacement of cerebellar vermis lesion. Acta Otolaryngol (Stockh) 99:452-458[Medline].
Igarashi M, Thompson GC, Thompson AM, Usami S (1988) Neurochemical and neuropharmacological studies on vestibular compensation/adaptation. In: Basic and applied aspects of vestibular function (Hwang JC, Daunton NG, Wilson VJ, eds), pp 89-97. Hong Kong: Hong Kong UP.
Ishikawa K, Igarashi M (1985) Effect of atropine and carbachol on vestibular compensation in squirrel monkeys. Am J Otolaryngol 6:290-296[Web of Science][Medline].
Ito M (1984) In: The cerebellum and neural control. New York: Raven.
Jeannerod M, Courjon JH, Flandrin JM, Schmid R (1981) Supravestibular control of vestibular compensation after hemilabyrinthectomy in the cat. In: Lesion-induced neuronal plasticity in sensorimotor systems (Flohr H, Precht W, eds), pp 208-220. New York: Springer.
Katayama S, Nisimaru N (1988) Parasagittal zonal pattern of olivonodular projections in rabbit cerebellum. Neurosci Res 5:424-438[Web of Science][Medline].
Kaufman GD, Anderson JH, Beitz AJ (1992) Brainstem fos expression following acute unilateral labyrinthectomy in the rat. NeuroReport 3:829-832[Web of Science][Medline].
Kitahara T, Takeda N, Saika T, Kubo T, Kiyama H (1995) Effects of MK801 on Fos expression in the rat brain after unilateral labyrinthectomy. Brain Res 700:182-190[Web of Science][Medline].
Leonard CS, Simpson JI, Graf W (1988) Spatial organization of visual messages of the rabbit's cerebellar flocculus. I. Typology of inferior olivary neurons of the dorsal cap of Kooy. J Neurophysiol 60:2073-2090[Abstract/Free Full Text].
Linden DJ, Connor JA (1995) Long-term synaptic depression. Annu Rev Neurosci 18:319-357[Web of Science][Medline].
Llinas R, Walton K (1979) Vestibular compensation: a distributed property of the central nervous system. In: Integration in the nervous system (Asanuma H, Wilson VF, eds), pp 145-166. Tokyo: Igaku-Shoin.
Luyten WHML, Sharp FR, Ryan AF (1986) Regional differences of brain glucose metabolic compensation after unilateral labyrinthectomy in rats: a [¹⁴C]2-deoxyglucose study. Brain Res 373:68-80[Web of Science][Medline].
McLean IW, Nakane PK (1974) Periodate-lysine-paraformaldehyde fixative for immunoelectron microscopy. J Histochem Cytochem 22:1077-1083[Abstract].
Ogita K, Miyamoto SI, Yamaguchi K, Koide H, Fujisawa N, Kikkawa U, Sahara S, Fukami Y, Nishizuka Y (1992) Isolation and characterization of $delta$ -subspecies of protein kinase C from rat brain. Proc Natl Acad Sci USA 89:1592-1596[Abstract/Free Full Text].
Ono Y, Fujii T, Ogita K, Kikkawa U, Igarashi K, Nishizuka Y (1988) The structure, expression, and properties of additional members of the protein kinase C family. J Biol Chem 263:6927-6932[Abstract/Free Full Text].
Patrickson JW, Bryant JH, Kaderkaro M, Kutyna FA (1985) A quantitative [¹⁴C]-2-deoxy-D-glucose study of brain stem nuclei during horizontal nystagmus induced by lesioning the lateral crista ampullaris of the rat. Exp Brain Res 60:227-234[Web of Science][Medline].
Precht W, Shimazu H, Markham CH (1966) A mechanism of central compensation of vestibular function following hemilabyrinthectomy. J Neurophysiol 29:996-1010[Free Full Text].
Ruigrok TJH, Osse R-J, Voogd J (1992) Organization of inferior olivary projections to the flocculus and ventral paraflocculus of the rat cerebellum. J Comp Neurol 316:129-150[Web of Science][Medline].
Saika T, Takeda N, Kiyama H, Kubo T, Tohyama M, Matsunaga T (1993) Changes in preproenkephalin mRNA after unilateral and bilateral labyrinthectomy in the rat medial vestibular nucleus. Mol Brain Res 19:237-240[Medline].
Shojaku H, Sato Y, Ikarashi K, Kawasaki T (1987) Topographical distribution of Purkinje cells in the uvula and the nodulus projecting to the vestibular nuclei in cats. Brain Res 416:100-112[Web of Science][Medline].
Smith PF, Curthoys IS (1989) Mechanisms of recovery following unilateral labyrinthectomy: a review. Brain Res Rev 14:155-180[Medline].
Smith PF, deWaele C, Vidal PP, Darlington CL (1991) Excitatory amino acid receptors in normal and abnormal vestibular function. Mol Neurobiol 5:369-387[Web of Science][Medline].
Tan J, Gerrits NM, Nanhoe R, Simpson JI, Voogd J (1995) Zonal organization of the climbing fiber projection to the flocculus and nodulus of the rabbit: a combined axonal tracing and acetylcholinesterase histochemical study. J Comp Neurol 356:23-50[Web of Science][Medline].
Winer BJ (1971) In: Statistical principles in experimental design. New York: McGraw-Hill.

Copyright ©1997 Society for Neuroscience   0270-6474/1997/174367-15$05.00/0

This article has been cited by other articles:

M. Faulstich, A. M. van Alphen, C. Luo, S. du Lac, and C. I. De Zeeuw
Oculomotor Plasticity During Vestibular Compensation Does Not Depend on Cerebellar LTD
J Neurophysiol, September 1, 2006; 96(3): 1187 - 1195.
[Abstract] [Full Text] [PDF]

A. R Johnston, J. R Seckl, and M. B Dutia
Role of the flocculus in mediating vestibular nucleus neuron plasticity during vestibular compensation in the rat
J. Physiol., December 15, 2002; 545(3): 903 - 911.
[Abstract] [Full Text] [PDF]

M. Ito
Cerebellar Long-Term Depression: Characterization, Signal Transduction, and Functional Roles
Physiol Rev, July 1, 2001; 81(3): 1143 - 1195.
[Abstract] [Full Text] [PDF]

Y. X. Li, T. Hashimoto, W. Tokuyama, Y. Miyashita, and H. Okuno
Spatiotemporal Dynamics of Brain-Derived Neurotrophic Factor mRNA Induction in the Vestibulo-Olivary Network during Vestibular Compensation
J. Neurosci., April 15, 2001; 21(8): 2738 - 2748.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (36)

Citing Articles via Google Scholar

Google Scholar

Articles by Goto, M. M.

Articles by Balaban, C. D.

Search for Related Content

PubMed

PubMed Citation

Articles by Goto, M. M.

Articles by Balaban, C. D.

Pubmed/NCBI databases
Substance via MeSH