Regulation of tyrosine hydroxylase expression intottering mouse Purkinje cells

Tottering (tg) mice inherit a missense mutation in the α_1A subunit of P/Q-type calcium channels. This mutation results in an increased density of L-type calcium channels in the cerebellum and abnormal regulation of tyrosine hydroxylase (TH) gene expression in a subset of cerebellar Purkinje cells, a cell type that does not normally express TH. The behavioral phenotype includes attacks of dyskinesia, which can be blocked by L-type calcium channel antagonists. To test the hypothesis that cerebellar TH mRNA expression can be manipulatedin vivo by L-type calcium channel blockade, control and tottering mice were chronically treated with the L-type calcium channel antagonist nimodipine. Chronic nimodipine treatment significantly reduced the expression of TH mRNA in tottering mouse Purkinje cells. This effect was observed without altering the increased density of L-type calcium channels in tottering mouse cerebella. Chronic nimodipine treatment had no effect on TH mRNA expression in tottering mouse catecholaminergic neurons, including those of the locus coeruleus and substantia nigra. However, a small reduction in TH mRNA expression in the substantia nigra of control mice was observed after drug treatment. These data suggest that the abnormal expression of TH in tottering mouse Purkinje cells is regulated by Purkinje cell excitability.     

Development of the paramedian lobule of the cerebellum in wild-type and tottering mice.

The mutant mouse tottering, (tg/tg), and the compound heterozygote mouse (tg/tg1a) exhibit three neurological disorders: ataxia, petit mal-like absence seizures and myoclonic intermittent movement disorders which are independent of the absence seizures. The tottering mouse carries an autosomal recessive single gene mutation on chromosome 8, and behavioral symptoms are first observed in the 3rd to 4th week of age. Using an additional genetic marker, Oligosyndactyly (Os), it is possible to distinguish tg/tg and tg/tg1a mice from wild-type mice at birth; nonaffected heterozygous littermates carry the Os mutation while tottering and compound heterozygous mice do not carry the Os gene. Similar to neurons found elsewhere in the brain, cerebellar Purkinje cells in both the wild-type and mutant mice were found to decrease in diameter with maturation. Forebrain weight, hindbrain weight, Purkinje cell dimensions and the thickness of the molecular layer in the paramedian lobule of the cerebellum in mutant mice were found to be reduced in mutants after, but not prior to the onset of behavioral symptoms.     

Tottering mouse motor dysfunction is abolished on the Purkinje cell degeneration (pcd) mutant background

Tottering (tg) mice inherit a recessive mutation of the calcium channel alpha 1A subunit gene, which encodes the pore-forming protein of P/Q-type voltage-sensitive calcium channels and is predominantly expressed in cerebellar granule and Purkinje neurons. The phenotypic consequences of the tottering mutation include ataxia, polyspike discharges, and an intermittent motor dysfunction best described as paroxysmal dystonia. These dystonic episodes induce c-fos mRNA expression in the cerebellar circuitry, including cerebellar granule and Purkinje neurons, deep cerebellar nuclei, and the postsynaptic targets of the deep nuclei. Cellular abnormalities associated with the mutation include hyperarborization of brainstem nucleus locus ceruleus axons and abnormal expression of L-type calcium channels in cerebellar Purkinje cells. Here, the role of these two distinct neural pathways in the expression of tottering mouse intermittent dystonia was assessed. Lesion of locus ceruleus axons with the neurotoxin N-(2-chloroethyl)-N-ethyl-2-bromobenzyl-amine (DSP-4) did not affect the frequency of tottering mouse dystonic episodes. In contrast, removal of cerebellar Purkinje cells with the Purkinje cell degeneration (pcd) mutation by generation of tg/tg; pcd/pcd double mutant mice completely eliminated tottering mouse dystonia. Further, the c-fos expression pattern of tg/tg; pcd/pcd double mutants following restraint was indistinguishable from that of wild-type mice, suggesting that the pcd lesion eliminated an essential link in this abnormal neural network. These data suggest that the cerebellar cortex, where the mutant gene is abundantly expressed, contributes to the expression of tottering mouse dystonic episodes.     

Rostrocaudal expression of antibody HNK-1-reactive glycolipids in mouse cerebellum: Relationship to developmental compartments and leaner mutation

Sulfoglucuronylglycolipids (SGGLs) and glycoproteins, reacting with monoclonal antibody HNK-1, are developmentally and spatially regulated in the mammalian cortex and cerebellum. It has been proposed that the HNK-1 carbohydrate epitope is involved in intercellular adhesion and cell-cell interactions. Biochemical analysis and immunocytochemical localization of SGGLs and other neolacto series glycolipids were studied in the leaner mutant mouse cerebellum, where a slow and progressive rostral to caudal degeneration occurs with a gradual loss of both granule cells and Purkinje cells. Biochemical analyses showed that SGGLs and other neolacto series of glycolipids were significantly decreased in the adult leaner cerebellum; however, HNK-1-reactive glycoproteins were not affected. By an immunocytochemical method which selectively localizes the lipid antigens, it is shown that SGGLs are primarily associated with Purkinje cell bodies and their dendrites in the molecular layer and in cerebellar nuclei where Purkinje cell axons terminate. At postnatal day 30 (P30), SGGL immunoreactivity (rSGGL-ir) in the leaner cerebellum was reduced moderately compared to normal littermates, which correlated with the minimal degree of Purkinje cell degeneration at this age in leaner and with the biochemical data. At P67 and P90, the SGGL-ir was significantly more reduced in the leaner as Purkinje cell degeneration proceeded. There was a direct correlation between loss of Purkinje cells and SGGL-ir in the cerebellar molecular layer. In both normal and young leaner cerebella, the SGGL-ir in different lobules was not uniform; there were distinct rostrocaudal and mediolateral differences. SGGL-ir was markedly more intense in rostral than in caudal lobules in the vermis, the dividing line being the region immediately caudal to the primary fissure and rostral to the declival sulcus. In the lateral cerebellum, the SGGL-ir was less intense than in the vermis and the rostrocaudal difference was not as pronounced. There was also nonuniformity in the intensity of staining in different folia. The rostrocaudal as well as mediolateral differences in the intensity of SGGL-ir were confirmed independently by biochemical analysis. The differential phenotypic expression of SGGLs and the selective susceptibility to Purkinje cell death in leaner mutant are discussed in relation to the known embryologic and ontogenetic compartmentation of cerebellum. © 1993 Wiley-Liss, Inc.     

Altered neuronal nitric oxide synthase expression in the cerebellum of calcium channel mutant mice

Tottering, rolling Nagoya, and leaner mutant mice all exhibit cerebellar ataxia to varying degrees, from mild (tottering mice) to severe (leaner mice). Collectively, these mice are regarded as tottering locus mutants because each of these mutant mice expresses a different autosomal recessive mutation in the gene coding for the alpha(1A) calcium ion channel protein, which is the pore forming subunit for P/Q-type high voltage activated calcium ion channels. These mutant mice all exhibit varying degrees of cerebellar dysfunction and neuronal cell death. Nitric oxide (NO) is an important messenger molecule in the central nervous system, especially in the cerebellum, and it is produced via the enzyme, nitric oxide synthase (NOS). We investigated expression of neuronal-NOS (n-NOS) in the cerebella of all three mutant mice, as revealed by NADPH-diaphorase (NADPH-d) histochemical staining, quantitation of n-NOS protein using Western blotting and quantitation of n-NOS mRNA using in situ hybridization. The expression of n-NOS mRNA and protein as well as the NADPH-d histochemical reaction were elevated in tottering and rolling Nagoya cerebella. n-NOS mRNA and the NADPH-d histochemical reaction were decreased in the leaner cerebellum, but the leaner mouse n-NOS protein concentration was not significantly different compared to age- and gender-matched controls. These findings suggest that NO may act as an important mediator in the production of the neuropathology observed in these mutant mice.     

Decreased gene expression of calretinin and ryanodine receptor type 1 in tottering mice

Tottering mice are a spontaneously occurring animal model of human absence epilepsy. They carry a mutation in the P/Q-type calcium channel alpha1A subunit gene which is highly expressed by cerebellar Purkinje cells. In this study, we investigated the role of calretinin and ryanodine receptor type 1 (RyR1) gene expression in the cerebellum of tottering mice. Cerebellar tissue specimens from four experimental groups were processed for in situ hybridization histochemistry (ISHH): (1) wild-type (+/+); (2) heterozygous (tg/+) and two homozygous groups; either (3) without occurrence of an episode of paroxysmal dyskinesia (tg/tg-N); or (4) after an episode of paroxysmal dyskinesia (tg/tg-P) that lasted about 45 min on average. Quantitative analysis showed a statistically significant decrease (p = 0.0001, ANOVA) of calretinin gene expression at the level of the simple lobule of the cerebellum in both homozygous groups compared to the wild-type and heterozygous groups. RyR1 was decreased in the flocculus of the cerebellum in both the tg/tg-N and tg/tg-P groups compared to wild type (p = 0.0174, ANOVA). These results suggest that calretinin gene expression, as well as other genes involved in regulation of calcium homeostasis, such as RyR1, may play a role in the biochemical functional alterations present in tottering mice.     

Cerebellar volume decreases in the tottering mouse are specific to the molecular layer

The volume of the cerebellum as a whole and the volume of the molecular layer per Purkinje cell in adult tottering () and tottering/leaner () mice were reduced when compared with normal age-matched wild type mice (+/+). No changes in the volume of the granule cell layer or white matter layer were detected, suggesting that the mutation effects were limited to the molecular layer of the cerebellum. The density of Purkinje cells and the total number of Purkinje cells did not vary between groups. The cerebellar and body weights were decreased in and mice compared with +/+ mice.     

Embryonic development of the rat cerebellum. III. Regional differences in the time of origin, migration, and settling of Purkinje cells

The time of origin, site of origin, migratory path and settling pattern of the Purkinje cells of the cerebellar hemispheres, anterior vermis, and posterior vermis were investigated in thymidine radiograms and plastic-embedded materials from rat embryos ranging in age from 15 to 22 days. In the hemispheres there is a rostral-to-caudal cytogenetic gradient: the Purkinje cells of lobulus simplex, crus I, and crus II are produced earlier than the Purkinje cells of the paramedian lobule and paraflocculus, followed by the Purkinje cells of the flocculus. The Purkinje cells of the vermis, in general, are generated later than those of the hemispheres, and with a reverse gradient from caudal to rostral: the Purkinje cells of the posterior vermis (lobules X-VI) being produced ahead of the Purkinje cells of the anterior posteriorly directed wedge of early-produced Purkinje cells through the vermis. Evidence was obtained that the Purkinje cells of the hemispheres derive from the lateral cerebellar primordium capping the lateral recess of the fourth ventricle anteriorly. The Purkinje cells of the anterior vermis originate from the subisthmal cerebellar primordium medially lining the isthmal canal. The Purkinje cells of the posterior vermis originate in the postisthmal cerebellar primordium overlying the tela choroidea caudally. The young Purkinje cells migrate from the neuroepithelium to the surface of the cerebellum in a strictly caudal-to-rostral order, paralleling the spread of the EGL superficially from posteroventral to anterodorsal. This pattern is independent of the time of origin of Purkinje cells. In the posterior vermis the earliest-settling Purkinje cells of the uvula follow a short radial course, and a discrete Purkinje layer is formed 3 days after they are generated. In the anterior vermis the Purkinje cells of lobulus centralis, which follow an anterodorsal migratory course, are still settling on day E22, 7 days after their production, presumably awaiting the fusion of the cerebellar base anteriorly. The fissura prima forms medially at the interface region of Purkinje cells derived from the postisthmal and subisthmal cerebellar primordia. For 1-2 days after their settling, the Purkinje cells of the newly forming lobules can be distinguished by certain cytological criteria from the Purkinje cells in the more caudally-situated, earlier-settled lobules.     

Abnormal expression of tyrosine hydroxylase immunoreactivity in cerebellar cortex of ataxic mutant mice

Expression of tyrosine hydroxylase (TH) was examined immunohistochemically in the cerebellum of two ataxic mutants, Rolling mouse Nagoya (RMN) and dilute-lethal mice (DL). In littermate controls of both mutants, a few TH-positive Purkinje cells were distributed sparsely and their number was smaller than in the mutants at any ages examined. In RMN, TH-positive Purkinje cells were distributed in lobule IX and X, and were arranged into parasagittal bands at 2 weeks of age. TH-positive Purkinje cells increased in number and were widely distributed throughout the vermis at 3 weeks of age. In adult RMN, TH-positive Purkinje cells were found in all lobules of the cerebellum. Their parasagittal bands also became evident in the hemisphere. In DL, TH-positive Purkinje cells were mainly distributed in vermal lobules IX and X, and the flocculus at 3 weeks of age. They were also found as bands in lobules IX and X. The results suggest that abnormal expression of TH in Purkinje cells may not be specific to the allelic group. Since TH promoter is activated by Ca2+, TH expression in the mutant Purkinje cells may predict neuronal dysfunction caused by alterations in cellular Ca2+ currents.     

Increased methionine-enkephalin levels in genetically epileptic (tg/tg) mice.

Recent experimental data indicate that endogenous brain ligands for the opioid receptors such as enkephalins, beta-endorphin (beta-End) and dynorphin (Dyn) may be involved in both generalized and partial seizures. The "tottering" (tg/tg) mouse provides an electrophysiological representation of generalized spontaneous human epilepsy. These mice exhibit behavioral absence seizures with accompanying spike-wave discharges. Methionine-enkephalin (M-Enk), beta-End and Dyn levels in various regions of brain were measured by radioimmunoassay (RIA) in 15-18-week-old tg/tg and control (+/+) mice to elucidate the relation between seizures and the opioid system. beta-End and Dyn levels were similar in tg/tg and +/+ mice. However, M-Enk levels were significantly increased in the striatum, cortex, pons and medulla of the tg/tg mice. Our data suggest that in the tottering mouse model of generalized epilepsy there is an alteration of enkephalinergic pathways and not of the endorphinergic or dynorphinergic pathways.     

Abnormal expression of tyrosine hydroxylase immunoreactivity in Purkinje cells precedes the onset of ataxia in dilute-lethal mice.

Expression of tyrosine hydroxylase (TH) immunostaining in the cerebellum was examined in dilute-lethal mice (DL) prior to and following the onset of ataxia. DL walked normally on postnatal days 7 and 8. Falling over when walking was exhibited by about 20% of DL on day 9 and by all DL by day 10. TH-positive Purkinje cells in lobules IX and X of the vermis of either ataxic or non-ataxic DL were clearly observed on day 9 when compared to control mice, and had drastically increased by day 10. These results revealed that abnormal TH expression occurred in some Purkinje cells of DL cerebella, preceding the onset of ataxia.     

Basal and drug-induced cAMP levels in cortical slices from the tottering mouse

Basal and drug-induced levels of cAMP were determined in cortical slices from mice which were homozygous for the tottering (tg/tg) gene defect as well as from co-isogenic controls (+/+). Basal levels of cAMP were 77 +/- 16% higher in tg/tg slices compared to the controls. This difference was abolished by exposure of the slices to propranolol, a beta-adrenergic receptor antagonist. Both isoproterenol and veratridine stimulated cAMP formation, but only small differences were observed in the cAMP levels in tg/tg and +/+ slices after this treatment. Of the veratridine-dependent increase in cAMP, approximately 40% was blocked by propranolol treatment of slices from both strains. The results suggest that a higher level of endogenous norepinephrine release in tottering mice contributes to an elevation of basal cAMP levels.     

Chronological and immunohistochemical observations of cerebellar dysplasia and vermis defect in the hereditary cerebellar vermis defect (CVD) rat

Hereditary cerebellar vermis defect (CVD) rats, a new neurological mutant, developed both cerebellar vermis defect and cerebellar dysplasia. Developmental alterations in the cerebellum of the CVD rats were studied chronologically and immunohistochemically. The earliest architectural abnormality was a maldevelopment of the inferior cerebellar peduncle from embryonic day 17 (E17), leading to an indistinct separation between the cerebellum and the pons. From E19, the CVD rats lacked vermis development and, therefore, the cerebellar hemispheres were fused. After birth, Purkinje cells and external granule cells (EGCs) penetrated into the pontine tissue, but retained their normal position until postnatal day 10. Cerebellar lamination began to be disturbed due to abnormal perivascular aggregations of the EGCs, resulting in convoluted and occasionally perivascular lamination. There were no Bergmann glia in the heterotopic cerebellum of the pons, and abnormally arranged Bergmann glia were observed in the mildly disorganized cerebellar hemispheres. Immunohistochemistry for calbindin revealed that abnormal orientation of the Purkinje cells might be related to the perivascular EGCs. Parvalbumin-immunopositive microneurons were seen only in the disarranged molecular layers, and synaptophysin-immunopositive cerebellar glomeruli were present in the afflicted internal granular layers. These findings suggest that perivascular EGCs may play an important role in cerebellar dysplasia and the developmental plasticity in the altered cerebellogenesis. Received: 1 October 1996 / Revised: 24 April 1997 / Revised, accepted: 11 June 1997     

Purkinje cell loss is due to a direct action of the weaver gene in Purkinje cells: evidence from chimeric mice

Within the cerebellum of the adult homozygous weaver mutant mouse there is an approximate 50% reduction in the number of vermal Purkinje cells. It is not known if this deficit is due to a primary action of the weaver gene or if the cell loss is due to a secondary effect of the weaver gene. We examined this question using chimeric mice, produced by fusing C57BL/6 homozygous or heterozygous weaver embryos (high beta-glucuronidase activity, Gusb) with C3HAw wild-type embryos (low beta-glucuronidase activity, Gush). Chimeric cerebella were stained for beta-glucuronidase activity and counts were made of the number of wv/- (Gusb) and +/+ (Gush) Purkinje cells. If the weaver gene acts intrinsically in the Purkinje cells, then the number of genetically wv/- and not +/+ Purkinje cells should be decreased. Alternatively, if the Purkinje cells are extrinsically affected by the weaver gene, then both wv/- and +/+ should be equally reduced. In this study, using comparative measures of chimerism and Purkinje cell numbers, only weaver Purkinje cells were reduced, while the +/+ Purkinje cells were unaffected in the chimera. These results indicate that the decrease in Purkinje cell number seen in the wv/wv and wv/+ cerebellum is a direct effect of the weaver gene. In concordance with previous work, the disorganization of the Purkinje cells in the cerebellum, however, results from an indirect effect of the weaver gene.     

Expression of heat-shock protein Hsp25 in mouse Purkinje cells during development reveals novel features of cerebellar compartmentation

The small heat shock protein Hsp25 is constitutively expressed in the adult mouse cerebellum by parasagittal stripes of Purkinje cells confined to the caudal central zone ( approximately lobules VI and VII), the nodular zone ( approximately ventral lobule IX and lobule X), and the paraflocculi/flocculi. During development several distinct phases in Hsp25 expression can be distinguished. Hsp25-immunopositive Purkinje cells are first seen at birth, when four clusters are visible in the vermis of lobules IV/V, and scattered Hsp25-immunoreactive Purkinje cells are seen in lobule VIII. By postnatal day 2/3, six narrow parasagittal stripes of Hsp25-immunopositive Purkinje cells are seen in the vermis of the anterior lobe. In the posterior lobules, most Purkinje cells in the vermis of lobules VIII and IX express Hsp25. This initial limited expression is followed by a phase of widespread expression (postnatal days 6-9) in which Hsp25 immunoreactivity is detected in virtually all Purkinje cells. This global cerebellar expression of Hsp25 then gradually disappears, first in the anterior zone and the hemispheres and subsequently in the posterior zone, to leave the restricted adult expression pattern. Western blotting analysis and immunoprecipitation with anti-Hsp25 suggest that all immunocytochemistry can be attributed the expression of Hsp25. Furthermore, visual deprivation had no effect on the development of Hsp25 expression in Purkinje cells, suggesting that visuomotor input is not responsible for the establishment of constitutive Hsp25 expression in the cerebellar cortex.     

Central adrenergic receptor changes in the inherited noradrenergic hyperinnervated mutant mouse tottering

Adrenergic receptor binding characteristics were analyzed in the mutant mouse tottering (tg/tg), a single gene locus autosomal recessive mutation causing hyperinnervation by locus coeruleus neurons of their target regions, which results in epilepsy, Instead of the expected down-regulation of receptors due to the hyperinnervation, both [³H]prazosin (α₁-receptor and [¹²⁵I]iodopindolol (β-receptor) binding were normal in the tg/tg hippocampus, spinal cord and slightly increased in the cerebellum. This lack of postsynaptic receptor modulation in the target cells, combined with increased levels of norepinephrine due to the aberrant axon growth, may be critical factors in the expression of the abnormal spike-wave absence seizures in the tg/tg mouse.     

Alterations in Intracellular Calcium Ion Concentrations in Cerebellar Granule Cells of the CACNA1A Mutant Mouse, Leaner, During Postnatal Development

Maintaining calcium ion (Ca²⁺) homeostasis is crucial for normal neuronal function. Altered Ca²⁺ homeostasis interferes with Ca²⁺ signaling processes and affects neuronal survival. In this study, we used homozygous leaner and tottering mutant mice, which carry autosomal recessive mutations in the gene coding for the α_1A pore forming subunit of Ca_V2.1 (P/Q-type) voltage-gated calcium channels (VGCC). Leaner mice show severe ataxia and epilepsy, while tottering mice are less severely affected. Leaner cerebellar granule cells (CGC) show extensive apoptotic cell death that peaks at postnatal (P) day 20 and continues into adulthood. Intracellular Ca²⁺ ([Ca²⁺]_i) concentrations in leaner and tottering mouse Purkinje cells have been described, but [Ca²⁺]_i concentrations have not been reported for granule cells, the largest neuronal population of the cerebellum. Using the ratiometric dye, Fura-2 AM, we investigated the role of Ca²⁺ homeostasis in CGC death during postnatal development by demonstrating basal [Ca²⁺]_i, depolarization induced Ca²⁺ transients, and Ca²⁺ transients after completely blocking Ca_V2.1 VGCC. From P20 onward, basal [Ca²⁺]_i levels in leaner CGC were significantly lower compared to age-matched wild-type CGC. We also compared basal [Ca²⁺]_i levels in leaner and wild-type CGC to basal [Ca²⁺]_i in tottering CGC. Potassium chloride induced depolarization revealed no significant difference in Ca²⁺ transients between leaner and wild-type CGC, indicating that even though leaner CGC have dysfunctional P/Q-type VGCC, Ca²⁺ transients after depolarization are the same. This suggests that other VGCC are compensating for the dysfunctional P/Q channels. This finding was further confirmed by completely blocking Ca_V2.1 VGCC using ω-Agatoxin IV-A.     

Noradrenergic sub-sensitivity in the cerebral cortex of the tottering mouse, a spontaneously epileptic mutant

The glycogenolytic action of norepinephrine (NE) was examined in the tottering mouse, a spontaneously epileptic mutant which presents a noradrenergic hyperinnervation of various CNS areas, including the cerebral cortex. The potency and efficacy of NE in promoting glycogenolysis were markedly decreased in cerebral cortical slices prepared from homozygous tottering (tg/tg) when compared to control C57BL/6j (+/+) mice, indicating a sub-sensitive response to a cellular action of NE. The metabolic nature of this adaptive change suggests that an impaired capacity of NE in mobilizing energy substrates may be related to the expression of the epileptic symptomatology in this mutant.     

Novel developmental boundary in the cerebellum revealed by zebrin expression in the lurcher (Lc/+) mutant mouse.

The cerebellar cortex contains at least two classes of Purkinje cells, which are organized into alternating arrays of parasagittal bands. The clearest demonstration of this compartmentation is the pattern of expression of a family of polypeptide antigens, the zebrins, which are expressed selectively by Purkinje cell subsets. Furthermore, anterograde tracing experiments show that the zebrin compartments are closely correlated with both afferent and efferent projection maps. The further subdivision of long parasagittal bands into smaller modules may occur through several different mechanisms, including the intrinsic cerebellar lobulation and the selective distribution of afferent terminal fields. However, while the longitudinal subdivisions are straightforwardly shown, the mediolateral boundaries are more subtle. In this report we describe a novel mediolateral and anteroposterior compartmentation boundary in mice, running across lobule VIII, that is revealed by the consequences of the lurcher (Lc/+) allele for zebrin expression. In normal mice zebrin compartmentation develops in several discrete stages: until postnatal day 5 (PD5) there is no zebrin expression; from PD5-PD7 zebrin is found only in the posterior lobe vermis, with immunoreactive Purkinje cells in lobules X, IX, and VIII but not elsewhere; from PD7-PD12 most Purkinje cells in the vermis become zebrin+; from PD12-PD15 immunoreactivity also appears in the hemispheres so that almost all Purkinje cells now are zebrin+; and finally, from PD15-PD25 zebrin is gradually suppressed in those Purkinje cells that are zebrin- in the adult until the mature pattern of parasagittal compartments is revealed. In the Lc/+ mutant the normal developmental progression is interrupted at around PD7. As a result, the pattern of zebrin expression becomes frozen at that stage when immunoreactive Purkinje cells are confined exclusively to the posterior lobe vermis. A reproducible boundary between expressing and nonexpressing zones runs mediolaterally across the dorsal surface of lobule VIII. Apart from zebrin expression itself, there are no obvious structural correlates of this transition. This mediolateral boundary identifies a developmental unit in the posterior lobe vermis of the cerebellum, and provides further evidence that the cerebellum is a highly heterogeneous structure.     

The localization of GABAA receptors in mice with mutations affecting the structure and connectivity of the cerebellum

The distribution of cerebellar [3H]muscimol binding sites was studied autoradiographically in normal C57BL/6J mice and in the weaver, reeler, Purkinje cell degeneration and staggerer mutant mice. In the normal 79-day-old mouse cerebellum, the highest concentration of [3H]muscimol binding sites was observed in the granule cell layer. A much lower grain density was present over the Purkinje cell and molecular layers and negligible numbers of binding sites were seen over the deep cerebellar nuclei and white matter. A significant decrease in [3H]muscimol labeling was observed over the cerebellar cortex of the 81-86-day-old weaver mutant; this was most pronounced in the vermis where granule cell loss was the greatest. Over the hemispheres, where fewer granule cells degenerate, a higher density of binding sites remained. In the 27-29-old reeler cerebellum, where Purkinje cells are malpositioned, no labeling was seen over the deep Purkinje cell masses. In the quasi-normal superficial cortex, labeling density over the surviving granule cell layer was only slightly decreased. In the 54-57-day-old Purkinje cell degeneration mutant, where essentially all Purkinje cells have disappeared by day 45, a 29% decrease in grain density over the granule cell layer was observed, while labeling was still present in the molecular layer. Virtually no [3H]muscimol labeling was detected over any part of the cerebellar cortex of the 25-27-day-old staggerer mutant (which lacks parallel fiber-Purkinje cell synapses), although clusters of surviving granule cells were present in significant numbers in the lateral aspects of the cortex. Our autoradiographic data indicate that GABAA receptors are associated with granule cells in both the molecular and granule cell layers. Furthermore, our results raise the possibility that the maintenance of receptor levels may be dependent upon synaptic contacts between the granule cell and its main postsynaptic target, the Purkinje cell.