Distinct ankyrin isoforms at neuron cell bodies and nodes of Ranvier resolved using erythrocyte ankyrin-deficient mice

Isoforms of ankyrin (ankyrinsR) immunologically related to erythrocyte ankyrin (ankyrinRo) are associated with distinct neuronal plasma membrane domains of functional importance, such as cell bodies and dendrites, axonal hillock and initial segments, and nodes of Ranvier. AnkyrinRo is expressed in brain, and accounts for at least one of the ankyrinR isoforms. Another ankyrin isoform of brain, ankyrinB, is encoded by a distinct gene and is immunologically distinct from ankyrinsR. Mutant mice with normoblastosis (nb/nb) constitute the first described genetic model of ankyrin deficiency: they display a severe hemolytic anemia due to a significantly reduced expression of the ankyrinRo gene in reticulocytes as well as brain (Peters L. L., C. S. Birkenmeier, R. T. Bronson, R. A. White, S. E. Lux, E. Otto, V. Bennett, A. Higgins, and J. E. Barker. 1991. J. Cell Biol. 114:1233-1241). In the present report, we distinguish between ankyrinRo and other ankyrinR isoforms using immunoblot analysis and immunofluorescence localization of ankyrinsR throughout the nervous system (forebrain, cerebellum, brain stem, spinal cord, and sciatic nerve) of nb/nb and normal mice. This is the first immunocytochemical characterization of the neurological component of the nb mutation and shows the following. (a) The isoform of ankyrin at the nodes of Ranvier and initial axonal segments is present in the nb/nb mice and does not cross-react with an ankyrinRo-specific antibody; this isoform, therefore, is distinct from both ankyrin isoforms identified in brain, ankyrinRo and ankyrinB, and is probably the product of a distinct gene and a unique component of the specialized membrane skeleton associated with nodes of Ranvier. (b) AnkyrinRo missing from nb/nb mice is selectively associated with neuronal cell bodies and dendrites, excluded from myelinated axons, and displays a selective pattern of expression in the nervous system whereby expression is almost ubiquitous in neurons of the cerebellum (Purkinje and granule cells) and spinal cord, and restricted to a very minor subset of neurons in hippocampus and neocortex of forebrain.     

Cellular Distribution of Gangliosides in the Developing Mouse Cerebellum: Analysis Using the Staggerer Mutant

The distribution of cerebellar gangliosides was studied in staggerer (sg/sg) mutant mice, where the majority of granule cells die after completing their migration across the molecular layer. In addition, the external granule cell layer in sg/sg mice persists longer than in normal mice. Moreover, in the sg/sg cerebellum, Purkinje cells are significantly reduced in number, and almost none have tertiary branchlet spines. The loss of Purkinje cells and granule cells in sg/sg mice is accompanied by an early-onset reactive gliosis that continues through adulthood. By correlating changes in ganglioside composition with the well-documented histological events of cerebellar development in normal and sg/sg mice, we obtained strong evidence for a nonrandom cellular distribution of gangliosides. The sharpest reduction in the GD1a content of sg/sg cerebellum occurred after 15 days of age, coincident with granule cell loss. GT1a, on the other hand, was significantly reduced from 15 through 150 days in the sg/sg mice. GD3 is a major ganglioside of the undifferentiated granule cell, but it becomes rapidly displaced by the more complex gangliosides with the onset of granule cell maturation. In the sg/sg mice, GD3 persisted at abnormally high levels from 15 to 28 days and then accumulated through adulthood. These findings, and those from other cerebellar mouse mutants, suggest that GD1a is enriched in granule cells and that GT1a is enriched in Purkinje cells. Our findings also suggest that GT1a is more concentrated in branchlet spines than in other regions of the Purkinje cell membrane. GT1b appears to be enriched in both granule cells and Purkinje cells, whereas GM1 appears to be enriched in myelin. Furthermore, the apparent persistence of the embryonic ganglioside GD3 in sg/sg mice results from an early-onset reactive gliosis, together with a partial retardation in granule cell maturation. The accumulation of GD3 beyond 28 days reflects the continued accretion of GD3 in reactive glia.     

Adenosine A1 Receptors Are Associated with Cerebellar Granule Cells

The cerebellum of mouse appears to have only the adenosine A1 receptor, which decreases adenylate cyclase activity, and not the A2 receptor, which increases adenylate cyclase activity. The adenosine analog N6-(L-phenylisopropyl)adenosine (PIA), stimulates the A1 receptor in a membrane preparation and decreases basal adenylate cyclase activity by 40%. The EC50 for PIA is approximately 50 nM. To associate the A1 receptor with a cerebellar cell type, three different neurological mutant mouse strains were studied: staggerer (Purkinje and granule cell defect), nervous (Purkinje cell defect), and weaver (granule cell defect). PIA was unable to effect a maximal decrease in adenylate cyclase activity of membranes prepared from cerebella of the staggerer and weaver mice in comparison with the respective littermate control mice. In contrast, membranes from nervous mice and their littermates showed similar PIA dose-response curves. Moreover, the diminished PIA response observed in the weaver cerebellum, when compared with the control littermate, was not detected in the striatum. This suggests no overall brain defect in the adenosine A1 receptors coupled to adenylate cyclase of the weaver mouse. We conclude that a loss of granule cells coincides with an attenuated response to PIA, implying that the A1 receptors are associated with the granule cells of the cerebellum.     

Differential Cellular Enrichment of Gangliosides in the Mouse Cerebellum: Analysis Using Neurological Mutants

Abstract: The cellular distribution of gangliosides in the cerebellum was studied in a series of adult mouse mutants that lose specific populations of neurons. The weaver ( wv ) mutation destroys the vast majority of granule cells, whereas the Purkinje cell degeneration mutation ( pcd ) destroys the vast majority of Purkinje cells. The staggerer ( sg ) and lurcher ( Lc ) mutations, on the other hand, destroy the vast majority of both granule and Purkinje cells. A proliferation of reactive glial cells, which occurs as a consequence of neuronal loss, has been reported in the sg/sg and pcd/pcd mutants, but not in the wv/wv mutant. Compared with the normal (+/+) mice, the concentration (μg/100 mg dry weight) of G_D1a was significantly reduced in those mutants that lost granule cells, but was not reduced in the pcd/pcd mutant. The concentration of G_TIa, on the other hand, was significantly reduced in those mutants that lost Purkinje cells, but was not reduced in the wv/wv mutant. A significant elevation in the concentration of G_D3, which may be related to the proliferation of reactive glial cells, was observed in the pcd/pcd, sglsg , and Lc /+ mutants, but was not observed in the wv/wv mutant. Because these ganglioside abnormalities were confined to the cerebellum, they cannot result from genetic defects in ganglioside metabolism. Instead, these abnormalities result from a differential enrichment of gangliosides in neural membranes. Our findings suggest that G_DT1a is more heavily concentrated in granule cells than Purkinje cells, whereas the opposite appears true for G_Tla. It also appears that GD3 is enriched in reactive glial cells and may play an important role during the morphological transformation of neural membranes.     

Bax and p53 are differentially involved in the regulation of caspase-3 expression and activation during neurodegeneration in Lurcher mice

Intrinsic Purkinje cell death in heterozygous Lurcher (Grid2Lc/+) mice is accompanied by the target-related death of granule cells and olivary neurons. The expression of pro-caspase-3 is increased in Grid2Lc/+ Purkinje cells and activated caspase-3 is detected in all three cell types before their death. Bax inactivation in Grid2Lc/+ mutants rescues granule cells but not Purkinje cells. Here, we show that, while Bax inactivation inhibits caspase-3 activation in both cell types, p53 inactivation does not affect caspase-3 activation and neuronal loss in Grid2Lc/+ mice. The up-regulation of pro-caspase-3 in Grid2Lc/+ Purkinje cells is Bax and p53 independent. These results suggest that Grid2Lc/+ granule cell death is dependent on Bax and caspase-3 activation, whereas several pathways can mediate Grid2Lc/+ Purkinje cell death.     

Increased inferior olivary neuron and cerebellar granule cell numbers in transgenic mice overexpressing the human Bcl-2 gene

Neuron-target interactions during development are critical for determining the final numbers of neurons in the nervous system. To investigate the role of Purkinje cells and programmed cell death in the regulation of afferent neuron numbers, we have counted olivary neurons and granule cells in two lines of transgenic mice (NSE73a and NSE71) that overexpress a human gene for bcl-2 (Hu-bcl-2) in Purkinje cells and olivary neurons, but not in granule cells. Bcl-2 overexpression in vivo reduces naturally occurring neuronal cell death and cell death following axotomy, target removal, or ischemia. Olivary neuron numbers in NSE73a and NSE71 transgenic mice are significantly increased compared to controls by 28% and 27%, respectively, while granule cell numbers are only increased in NSE73a mice (29% above controls). We have previously shown that Purkinje cell number is increased by 43% in NSE73a transgenics and by 23% in NSE71 transgenics. The ratio of Purkinje cells to olivary neurons is not significantly different between the control and transgenic mice, while the ratio of granule cells to Purkinje cells is significantly decreased in the NSE71 transgenic mice compared to controls and NSE73a transgenics. The increased numbers of olivary neurons suggest that bcl-2 overexpression rescues these neurons from programmed cell death. The increase in granule cell number in only one transgenic line is discussed with respect to hypotheses that Purkinje cells regulate both granule cell progenitor proliferation and the survival of differentiated granule cells. © 1997 John Wiley & Sons, Inc. J Neurobiol 32: 502–516, 1997     

Differential expression of T-type calcium channels in P/Q-type calcium channel mutant mice with ataxia and absence epilepsy

Mutations in P/Q-type calcium channels generate common phenotypes in mice and humans, which are characterized by ataxia, paroxysmal dyskinesia, and absence seizures. Subsequent functional changes of T-type calcium channels in thalamus are observed in P/Q-type calcium channel mutant mice and these changes play important roles in generation of absence seizures. However, the changes in T-type calcium channel function and/or expression in the cerebellum, which may be related to movement disorders, are still unknown. The leaner mouse exhibits severe ataxia, paroxysmal dyskinesia, and absence epilepsy due to a P/Q-type calcium channel mutation. We investigated changes in T-type calcium channel expression in the leaner mouse thalamus and cerebellum using quantitative real-time polymerase chain reaction (qRT-PCR) and quantitative in situ hybridization histochemistry (ISHH). qRT-PCR analysis showed no change in T-type calcium channel alpha 1G subunit (Cav3.1) expression in the leaner thalamus, but a significant decrease in alpha 1G expression in the whole leaner mouse cerebellum. Interestingly, quantitative ISHH revealed differential changes in alpha 1G expression in the leaner cerebellum, where the granule cell layer showed decreased alpha 1G expression while Purkinje cells showed increased alpha 1G expression. To confirm these observations, the granule cell layer and the Purkinje cell layer were laser capture microdissected separately, then analyzed with qRT-PCR. Similar to the observation obtained by ISHH, the leaner granule cell layer showed decreased alpha 1G expression and the leaner Purkinje cell layer showed increased alpha 1G expression. These results suggest that differential expression of T-type calcium channels in the leaner cerebellum may be involved in the observed movement disorders.     

Presence of protein I, a phosphoprotein associated with synaptic vesicles, in cerebellar granule cells

Abstract: The cerebellar levels of Protein I, a synapse-specific neuronal phosphoprotein, have been investigated in the cerebellar mouse mutants staggerer ( sg ), weaver ( wv ), nervous ( nr ), and Purkinje cell degeneration ( pcd ). The Protein I concentration was reduced by about 66% in sg and wv mutants, representing a 90% loss of Protein I per cerebellum. A heterozygote effect was observed in the wv mutant. These results indicate that a great majority of Protein I in the normal cerebellum may be present in the granule cells. in nr mutants the cerebellar Protein I concentration was reduced by only 12% in 62-day-old mice, suggesting that Purkinje cells contribute little to cerebellar Protein I. However, a greater reduction was observed in pcd mutants, which may reflect on the nature of the pcd mutation.     

The cerebellar deficient folia (cdf) gene acts intrinsically in Purkinje cell migrations

Cerebellar deficient folia (cdf) is a recently identified mouse mutation causing ataxia and cerebellar abnormalities including lobulation defects and abnormal placement of a specific subset of Purkinje cells. To understand the etiology of the cerebellar defects in cdf mutant mice, we examined postnatal development of the cdf/cdf cerebellum. Our results demonstrate that Purkinje cell ectopia and foliation defects are apparent at birth, suggesting the cdf mutation disrupts the positioning of many, but not all, Purkinje cells during development. In addition to cerebellar abnormalities, we observed lamination defects in the hippocampus of cdf mutant mice, although neocortical defects were not seen. Furthermore, ectopic Purkinje cells in cdf/cdf mice express an increased level of Dab1 protein, as previously observed in mice with mutations in genes in the reelin signaling pathway. Lastly, analysis of cdf <-->ROSA26 chimeric mice demonstrated that the cdf mutation is intrinsic to Purkinje cells. We suggest that the cdf gene product is required in a subset of Purkinje cells, possibly to respond to Reelin signals.     

Interactions between cerebellar Purkinje cells and their associated astrocytes

Some neurons, including cerebellar Purkinje cells, are completely ensheathed by astrocytes. When granule cell neurons and functional glia were eliminated from newborn mouse cerebellar cultures by initial exposure to a DNA synthesis inhibitor, Purkinje cells lacked glial sheaths and there was a tremendous sprouting of Purkinje cell recurrent axon collaterals, terminals of which hyperinnervated Purkinje cell somata, including persistent somatic spines, and formed heterotypical synapses with Purkinje cell dendritic spines, sites usually occupied by parallel fiber (granule cell axon) terminals. Purkinje cells in such preparations failed to develop complex spikes when recorded from intracellularly, and their membrane input resistances were low, making them less sensitive to inhibitory input. If granule cells and oligodendrocytes were eliminated, but astrocytes were not compromised, sprouting of recurrent axon collaterals occurred and their terminals projected to Purkinje cell dendritic spines, but the Purkinje cells had astrocytic sheaths, their somata were not hyperinnervated, the somatic spines had disappeared, complex spike discharges predominated, and membrane input resistance was like that of Purkinje cells in untreated control cultures. When cerebellar cultures without granule cells and glia were transplanted with granule cells and/or glia from another source, a series of changes occurred that included stripping of excess Purkinje cell axosomatic synapses by astrocytic processes, reduction of heterotypical axospinous synapses in the presence of astrocytes, disappearance of Purkinje cell somatic spines with astrocytic ensheathment, and proliferation of Purkinje cell dendritic spines after the introduction of astrocytes. Dendritic spine proliferation was followed by formation of homotypical axospinous synapses when granule cells were present or persistence as unattached spines in the absence of granule cells. The results of these studies indicate that astrocytes regulate the numbers of Purkinje cell axosomatic and axospinous synapses, induce Purkinje cell dendritic spine proliferation, and promote the structural and functional maturation of Purkinje cells.     

ATP-Dependent Glutamate Uptake into Synaptic Vesicles from Cerebellar Mutant Mice

The ATP-dependent glutamate uptake system in synaptic vesicles prepared from mouse cerebellum was characterized, and the levels of glutamate uptake were investigated in the cerebellar mutant mice, staggerer and weaver, whose main defect is the loss of cerebellar granule cells, and the nervous mutant, whose main defect is the loss of Purkinje cells. The ATP-dependent glutamate uptake is stimulated by low concentrations of chloride, is insensitive to aspartate, and is inhibited by agents known to dissipate the electrochemical proton gradient. These properties are similar to those of the glutamate uptake system observed in the highly purified synaptic vesicles prepared from bovine cortex. The ATP-dependent glutamate uptake system is reduced by 68% in the staggerer and 57-67% in the weaver mutant; these reductions parallel the substantial loss of granule cells in those mutants. In contrast, the cerebellar levels of glutamate uptake are not altered significantly in the nervous mutant, which has lost Purkinje cells, but not granule cells. In view of evidence that granule cells are glutamatergic neurons and Purkinje cells are GABAergic neurons, these observations support the notion that the ATP-dependent glutamate uptake system is present in synaptic vesicles of glutamatergic neurons.     

A minimal ankyrin promoter linked to a human gamma-globin gene demonstrates erythroid specific copy number dependent expression with minimal position or enhancer dependence in transgenic mice

In red blood cells ankyrin (ANK-1) provides the primary linkage between the erythrocyte membrane skeleton and the plasma membrane. We have previously demonstrated that a 271-bp 5'-flanking region of the ANK-1 gene has promoter activity in erythroid, but not non-erythroid, cell lines. To determine whether the ankyrin promoter could direct erythroid-specific expression in vivo, we analyzed transgenic mice containing the ankyrin promoter fused to the human (A)gamma-globin gene. Sixteen of 17 lines expressed the transgene in erythroid cells indicating nearly position-independent expression. We also observed a significant correlation between the level of Ank/(A)gamma-globin mRNA and transgene copy number. The level of Ank/(A)gamma mRNA averaged 11% of mouse alpha-globin mRNA per gene copy at all developmental stages. The addition of the HS2 enhancer from the beta-globin locus control region to the Ank/(A)gamma-globin transgene resulted in Ank/(A)gamma-globin mRNA expression in embryonic and fetal erythroid cells in six of eight lines but resulted in absent or dramatically reduced levels of Ank/(A)gamma-globin mRNA in adult erythroid cells in eight of eight transgenic lines. These data indicate that the minimal ankyrin promoter contains all sequences necessary and sufficient for erythroid-specific, copy number-dependent, position-independent expression of the human (A)gamma-globin gene.     

Development and expression of cytoplasmic antigens in Purkinje cells recognized by monoclonal antibodies

Summary Five monoclonal antibodies reacting with intracellular constituents of Purkinje cells were investigated by means of indirect immunofluorescence on fresh-frozen sections of the cerebellum and retina from developing and adult normal and mutant mice. Antibodies PC1, PC2 and PC3, which recognize Purkinje cells, but no other cerebellar neuron type, label these cells from day 4 onward. PC4 antigen is expressed in addition to Purkinje cells also in granule cells and neurons of deep cerebellar nuclei and appears in Purkinje cells at day 4. M1 antigen (Lagenaur et al. 1980) is first detectable in Purkinje cell bodies by day 5; it is also detectable in deep cerebellar neurons. In the adult retina, only PC4 antigen is detectably expressed and is localized in the inner segments of photoreceptor cells.The neurological mutants weaver, reeler,jimpy and wobbler show detectable levels of these antigens in Purkinje cells. However, the mutants staggerer and Purkinje cell degeneration are abnormal in expression PC1, PC2, PC3, and M1 antigens. Staggerer never starts to express the antigens during development, whereas Purkinje cell degeneration first expresses the antigens, but then loses antigen expression after day 23. PC4 antigen is detectable in the remaining Purkinje cells in staggerer and Purkinje cell degeneration mice at all ages tested in this study. Deep cerebellar neurons are positive for both antigens, PC4 and M1, in all mutants and at all ages studied. In retinas of staggerer and Purkinje cell degeneration mutants, PC4 antigen is normally detectable in the inner segments of photoreceptor cells, even when these have started to degenerate in the case of Purkinje cell degeneration.     

Murine erythrocyte ankyrin cDNA: highly conserved regions of the regulatory domain

Ankyrin is an essential link between cytoskeletal proteins, such as spectrin, and membrane bound proteins, such as protein 3, the erythrocyte anion exchanger. Although the amino acid structure of human ankyrin is known, the functional regions have been only partially defined. Sequence comparisons between mouse and human ankyrin offer one mechanism of identifying highly conserved regions that probably have functional significance. We report the isolation and sequencing of a series of overlapping murine erythroid ankyrin (Ank-1) cDNAs from spleen and reticulocyte libraries (total span 6238 bp) and identify potentially important regions of murine-human reticulocyte ankyrin homology. Comparison of the predicted peptide sequences of mouse and human erythroid ankyrins shows that these ankyrins are highly conserved in both the N-terminal, protein 3 binding domain (96% amino acid identity) and in the central spectrin-binding domain (97% identity), but differ in the C-terminal regulatory domain (79% identity). However, the C-terminal regulatory domain contains two regions of peptide sequence that are perfectly conserved. We postulate these regions are important in the regulatory functions of this domain.     

Cellular localization of gangliosides in the developing mouse cerebellum: analysis using the weaver mutant

Abstract: The distribution of gangliosides was studied in the weaver ( wv/wv ) mutant mouse, where the vast majority of postmitotic granule cell neurons die prior to their differentiation. The wv mutation also shows a dosage effect, as granule cell migration is slowed or retarded in the + /wv heterozygotes. By correlating changes in ganglioside composition with the well-documented histological events that occur during cerebellar development in the normal (+/+), heterozygous ( +/wv ), and weaver ( wv/ wv ) mutant mice, information was obtained on the cellular localization and function of gangliosides. Ganglioside G_M1 may be enriched in granule cell growth cones and play an important role in neurite outgrowth. A striking accumulation of G_M1, which may result from altered metabolism, occurred in the adult wvlwv mice. G_D3 was heavily concentrated in undifferentiated granule cells, but was rapidly displaced by the more complex gangliosides during differentiation. G_D1a became enriched in granule cells during formation of synaptic and dendritic membranes, whereas G_T1a appeared enriched in Purkinje cell synaptic spines. A possible fucose-containing ganglioside was quantitated only in the wvlwv mice. Ganglioside G_T1b became enriched in granule cells during synaptogenesis, whereas G_Q1b became enriched in these cells after synaptogenesis. The concentrations of G_T1b and especially G_Q1b increased continuously with age. Our results provide further evidence for a differential cellular enrichment of gangliosides in the mouse cerebellum and also suggest that certain gangliosides may be differentially distributed within the membranes of these cells at various stages of development.     

Purkinje cell fate in staggerer mutants: agenesis versus cell death

Staggerer (sg/sg) is an autosomal recessive mutation in an orphan nuclear hormone receptor gene, RORalpha, that causes a cell-autonomous, lineage-specific block in the development of the Purkinje cell. Purkinje cell number is reduced by about 75-90% in adult mutants, and many of the surviving cells are small and ectopically positioned. To determine whether Purkinje cell numbers are reduced owing to either agenesis or cell death, cohorts of Purkinje cells were labeled with the birth-date marker bromodeoxyuridine (BrdU) at embryonic day (E) 10.5 or E11.5. The total number of BrdU-labeled profiles was then compared between cerebella from wild-type mice, heterozygous staggerer, and staggerer mutants at E17.5 and postnatal day (P)5. There was no significant difference between sg/sg mutants and +/sg or +/+ controls in the number of BrdU-labeled profiles or in cerebellar volumes in the E17 embryos. By P5, however, cerebellar volume was significantly reduced in the sg/sg mutants compared to controls (p <.005) and the number of BrdU-labeled profiles was reduced by 33% following E11.5 BrdU injections (p <.02). The results suggest that Purkinje cell genesis is not affected by the staggerer mutation and that Purkinje cell loss begins some time after E17. RORalpha is highly expressed in Purkinje cells by E14, so the delay between initial RORalpha expression and sg/sg Purkinje cell loss suggests that the staggerer mutation does not directly cause Purkinje cell death.     

Transgenic mice expressing F3/contactin from the TAG-1 promoter exhibit developmentally regulated changes in the differentiation of cerebellar neurons

F3/contactin (CNTN1) and TAG-1 (CNTN2) are closely related axonal glycoproteins that are differentially regulated during development. In the cerebellar cortex TAG-1 is expressed first as granule cell progenitors differentiate in the premigratory zone of the external germinal layer. However, as these cells begin radial migration, TAG-1 is replaced by F3/contactin. To address the significance of this differential regulation, we have generated transgenic mice in which F3/contactin expression is driven by TAG-1 gene regulatory sequences, which results in premature expression of F3/contactin in granule cells. These animals (TAG/F3 mice) display a developmentally regulated cerebellar phenotype in which the size of the cerebellum is markedly reduced during the first two postnatal weeks but subsequently recovers. This is due in part to a reduction in the number of granule cells, most evident in the external germinal layer at postnatal day 3 and in the inner granular layer between postnatal days 8 and 11. The reduction in granule cell number is accompanied by a decrease in precursor granule cell proliferation at postnatal day 3, followed by an increase in the number of cycling cells at postnatal day 8. In the same developmental window the size of the molecular layer is markedly reduced and Purkinje cell dendrites fail to elaborate normally. These data are consistent with a model in which deployment of F3/contactin on granule cells affects proliferation and differentiation of these neurons as well as the differentiation of their synaptic partners, the Purkinje cells. Together, these findings indicate that precise spatio-temporal regulation of TAG-1 and F3/contactin expression is critical for normal cerebellar morphogenesis.     

Differential expression of T‐type calcium channels in P/Q‐type calcium channel mutant mice with ataxia and absence epilepsy

Mutations in P/Q‐type calcium channels generate common phenotypes in mice and humans, which are characterized by ataxia, paroxysmal dyskinesia, and absence seizures. Subsequent functional changes of T‐type calcium channels in thalamus are observed in P/Q‐type calcium channel mutant mice and these changes play important roles in generation of absence seizures. However, the changes in T‐type calcium channel function and/or expression in the cerebellum, which may be related to movement disorders, are still unknown. The leaner mouse exhibits severe ataxia, paroxysmal dyskinesia, and absence epilepsy due to a P/Q‐type calcium channel mutation. We investigated changes in T‐type calcium channel expression in the leaner mouse thalamus and cerebellum using quantitative real‐time polymerase chain reaction (qRT‐PCR) and quantitative in situ hybridization histochemistry (ISHH). qRT‐PCR analysis showed no change in T‐type calcium channel α1G subunit (Cav3.1) expression in the leaner thalamus, but a significant decrease in α1G expression in the whole leaner mouse cerebellum. Interestingly, quantitative ISHH revealed differential changes in α1G expression in the leaner cerebellum, where the granule cell layer showed decreased α1G expression while Purkinje cells showed increased α1G expression. To confirm these observations, the granule cell layer and the Purkinje cell layer were laser capture microdissected separately, then analyzed with qRT‐PCR. Similar to the observation obtained by ISHH, the leaner granule cell layer showed decreased α1G expression and the leaner Purkinje cell layer showed increased α1G expression. These results suggest that differential expression of T‐type calcium channels in the leaner cerebellum may be involved in the observed movement disorders. © 2004 Wiley Periodicals, Inc. J Neurobiol, 2005     

Sulfoglucuronyl Neolactoglycolipids in Adult Cerebellum: Specific Absence in Murine Mutants with Purkinje Cell Abnormality

It is shown here that glycolipids of the sulfoglucuronyl neolacto series (SGGLs) are present in the adult rodent cerebellum. SGGLs were not detected in the cerebellar murine mutants lurcher, Purkinje cell degeneration, and staggerer, in which Purkinje cell loss is the primary defect. SGGLs were present, however, in normal amounts in weaver and reeler mutants, in which there is a major and relatively specific loss of granule cells without obvious deficiency in Purkinje cells. In the myelin-deficient quaking mutant, the expression of SGGLs also was nearly normal. The loss of SGGLs in Purkinje cell-deficient mutants was specific, since most of the major lipids were not affected significantly and only the percentage composition of other lipids, such as sulfatides and gangliosides, was altered in the mutants. These and other results strongly suggest that SGGLs and other glycolipids of the paragloboside family are localized specifically in Purkinje cells and their arbors in the adult cerebellum. This is the first demonstration of the localization of a specific glycolipid and its analogs in a specific cell type in the nervous system.     

Forward genetic screen of mouse reveals dominant missense mutation in the P/Q-type voltage-dependent calcium channel, CACNA1A

Dominant mutations of the P/Q-type Ca(2+) channel (CACNA1A) underlie several human neurological disorders, including episodic ataxia type 2, familial hemiplegic migraine 1 (FHM1) and spinocerebellar ataxia 6, but have not been found previously in the mouse. Here we report the first dominant ataxic mouse model of Cacna1a mutation. This Wobbly mutant allele of Cacna1a was identified in an ethylnitrosourea (ENU) mutagenesis dominant behavioral screen. Heterozygotes exhibit ataxia from 3 weeks of age and have a normal life span. Homozygotes have a righting reflex defect from postnatal day 8 and later develop severe ataxia and die prematurely. Both heterozygotes and homozygotes exhibit cerebellar atrophy with focal reduction of the molecular layer. No obvious loss of Purkinje cells or decrease in size of the granule cell layer was observed. Real-time polymerase chain reaction revealed altered expression levels of Cacna1g, Calb2 and Th in Wobbly cerebella, but Cacna1a messenger RNA and protein levels were unchanged. Positional cloning revealed that Wobbly mice have a missense mutation leading to an arginine to leucine (R1255L) substitution, resulting in neutralization of a positively charged amino acid in repeat III of voltage sensor segment S4. The dominance of the Wobbly mutation more closely resembles patterns of CACNA1A mutation in humans than previously described mouse recessive mutants (tottering, leaner, rolling Nagoya and rocker). Positive-charge neutralization in S4 has also been shown to underlie several cases of human dominant FHM1 with ataxia. The Wobbly mutant thus highlights the importance of the voltage sensor and provides a starting point to unravel the neuropathological mechanisms of this disease.