Cerebellar alterations in the weaver mouse

The Spinocerebellar Ataxia 34-Causing W246G ELOVL4 Mutation Does Not Alter Cerebellar Neuron Populations in a Rat Model

Spinocerebellar ataxia 34 (SCA34) is an autosomal dominant disease that arises from point mutations in the fatty acid elongase, Elongation of Very Long Chain Fatty Acids 4 (ELOVL4), which is essential for the synthesis of Very Long Chain-Saturated Fatty Acids (VLC-SFA) and Very Long Chain-Polyunsaturated Fatty Acids (VLC-PUFA) (28-34 carbons long). SCA34 is considered a neurodegenerative disease. However, a novel rat model of SCA34 (SCA34-KI rat) with knock-in of the W246G ELOVL4 mutation that causes human SCA34 shows early motor impairment and aberrant synaptic transmission and plasticity without overt neurodegeneration. ELOVL4 is expressed in neurogenic regions of the developing brain, is implicated in cell cycle regulation, and ELOVL4 mutations that cause neuroichthyosis lead to developmental brain malformation, suggesting that aberrant neuron generation due to ELOVL4 mutations might contribute to SCA34. To test whether W246G ELOVL4 altered neuronal generation or survival in the cerebellum, we compared the numbers of Purkinje cells, unipolar brush cells, molecular layer interneurons, granule and displaced granule cells in the cerebellum of wildtype, heterozygous, and homozygous SCA34-KI rats at four months of age, when motor impairment is already present. An unbiased, semi-automated method based on Cellpose 2.0 and ImageJ was used to quantify neuronal populations in cerebellar sections immunolabeled for known neuron-specific markers. Neuronal populations and cortical structure were unaffected by the W246G ELOVL4 mutation by four months of age, a time when synaptic and motor dysfunction are already present, suggesting that SCA34 pathology originates from synaptic dysfunction due to VLC-SFA deficiency, rather than aberrant neuronal production or neurodegeneration.

Enhancement of endogenous midbrain neurogenesis by microneurotrophin BNN-20 after neural progenitor grafting in a mouse model of nigral degeneration

JOURNAL/nrgr/04.03/01300535-202406000-00036/inline-graphic1/v/2023-10-30T152229Z/r/image-tiff

We have previously shown the neuroprotective and pro-neurogenic activity of microneurotrophin BNN-20 in the substantia nigra of the “weaver” mouse, a model of progressive nigrostriatal degeneration. Here, we extended our investigation in two clinically-relevant ways. First, we assessed the effects of BNN-20 on human induced pluripotent stem cell-derived neural progenitor cells and neurons derived from healthy and parkinsonian donors. Second, we assessed if BNN-20 can boost the outcome of mouse neural progenitor cell intranigral transplantations in weaver mice, at late stages of degeneration. We found that BNN-20 has limited direct effects on cultured human induced pluripotent stem cell-derived neural progenitor cells, marginally enhancing their differentiation towards neurons and partially reversing the pathological phenotype of dopaminergic neurons generated from parkinsonian donors. In agreement, we found no effects of BNN-20 on the mouse neural progenitor cells grafted in the substantia nigra of weaver mice. However, the graft strongly induced an endogenous neurogenic response throughout the midbrain, which was significantly enhanced by the administration of microneurotrophin BNN-20. Our results provide straightforward evidence of the existence of an endogenous midbrain neurogenic system that can be specifically strengthened by BNN-20. Interestingly, the lack of major similar activity on cultured human induced pluripotent stem cell-derived neural progenitors and their progeny reveals the in vivo specificity of the aforementioned pro-neurogenic effect.

Cerebellar Abiotrophy Across Domestic Species

Cerebellar abiotrophy (CA) is a neurodegenerative disorder affecting the cerebellum and occurs in multiple species. Although CA is well researched in humans and mice, domestic species such as the dog, cat, sheep, cow, and horse receive little recognition. This may be due to few studies addressing the mechanism of CA in these species. However, valuable information can still be extracted from these cases. A review of the clinicohistologic phenotype of CA in these species and determining the various etiologies of CA may aid in determining conserved and required pathways necessary for proper cerebellar development and function. This review outlines research approaches of studies of CA in domestic species, compared to the approaches used in mice, with the objective of comparing CA in domestic species while identifying areas for further research efforts.

Behavioral effects of neonatal lesions on the cerebellar system

Several rodent models with spontaneous mutations causing cerebellar pathology are impaired in motor functions during the neonatal period, including Grid2(Lc), Rora(sg), Dab1(scm), Girk2(Wv), Lmx1a(dr-sst), Myo5a(dn), Inpp4a(wbl), and Cacna1a(rol) mice as well as shaker and dystonic rats. Deficits are also evident in murine null mutants such as Zic1, Fgfr1/FgFr2, and Xpa/Ercc8. Behavioral deficits are time-dependent following X-irradiated- or aspiration-induced lesions of the cerebellum in rats. In addition, motor functions are deficient after lesions in cerebellar-related pathways. As in animal subjects, sensorimotor disturbances have been described in children with cerebellar lesions. These results underline the importance of the cerebellum and its connections in the development of motor functions.

From mice to men: lessons from mutant ataxic mice

Ataxic mutant mice can be used to represent models of cerebellar degenerative disorders. They serve for investigation of cerebellar function, pathogenesis of degenerative processes as well as of therapeutic approaches. Lurcher, Hot-foot, Purkinje cell degeneration, Nervous, Staggerer, Weaver, Reeler, and Scrambler mouse models and mouse models of SCA1, SCA2, SCA3, SCA6, SCA7, SCA23, DRPLA, Niemann-Pick disease and Friedreich ataxia are reviewed with special regard to cerebellar pathology, pathogenesis, functional changes and possible therapeutic influences, if any. Finally, benefits and limitations of mouse models are discussed.

Neural injury alters proliferation and integration of adult-generated neurons in the dentate gyrus

Neural plasticity following brain injury illustrates the potential for regeneration in the central nervous system. Lesioning of the perforant path, which innervates the outer two-thirds of the molecular layer of the dentate gyrus, was one of the first models to demonstrate structural plasticity of mature granule cells (Parnavelas et al., 1974; Caceres and Steward, 1983; Diekmann et al., 1996). The dentate gyrus also harbors a continuously proliferating population of neuronal precursors that can integrate into functional circuits and show enhanced short-term plasticity (Schmidt-Hieber et al., 2004; Abrous et al., 2005). To examine the response of adult-generated granule cells to unilateral complete transection of the perforant path in vivo, we tracked these cells using transgenic POMC-EGFP mice or by retroviral expression of GFP. Lesioning triggered a marked proliferation of newborn neurons. Subsequently, the dendrites of newborn neurons showed reduced complexity within the denervated zone, but dendritic spines still formed in the absence of glutamatergic nerve terminals. Electron micrographs confirmed the lack of intact presynaptic terminals apposing spines on mature cells and on newborn neurons. Newborn neurons, but not mature granule cells, had a higher density of dendritic spines in the inner molecular layer postlesion accompanied by an increase in miniature EPSC amplitudes and rise times. Our results indicate that injury causes an increase in newborn neurons and lamina-specific synaptic reorganization indicative of enhanced plasticity. The presence of de novo dendritic spines in the denervated zone suggests that the postlesion environment provides the necessary signals for spine formation.

Dendritic spines and development: towards a unifying model of spinogenesis--a present day review of Cajal's histological slides and drawings

Dendritic spines receive the majority of excitatory connections in the central nervous system, and, thus, they are key structures in the regulation of neural activity. Hence, the cellular and molecular mechanisms underlying their generation and plasticity, both during development and in adulthood, are a matter of fundamental and practical interest. Indeed, a better understanding of these mechanisms should provide clues to the development of novel clinical therapies. Here, we present original results obtained from high-quality images of Cajal's histological preparations, stored at the Cajal Museum (Instituto Cajal, CSIC), obtained using extended focus imaging, three-dimensional reconstruction, and rendering. Based on the data available in the literature regarding the formation of dendritic spines during development and our results, we propose a unifying model for dendritic spine development.

Intrinsic versus extrinsic determinants during the development of Purkinje cell dendrites

The peculiar shape and disposition of Purkinje cell (PC) dendrites, planar and highly branched, offers an optimal model to analyze cellular and molecular regulators for the acquisition of neuronal dendritic trees. During the first 2 weeks after the end of the proliferation period, PCs undergo a 2-phase remodeling process of their dendrites. The first phase consists in the complete retraction of the primitive but extensive dendritic tree, together with the formation of multiple filopodia-like processes arising from the cell body. In the second phase, there is a progressive disappearance of the somatic processes along with rapid growth and branching of the mature dendrite. Mature Purkinje cell dendrites bear two types of spiny protrusions, named spine and thorn. The spines are numerous, elongated, located at the distal dendritic compartment and form synapses with parallel fibers, whereas the thorns are shorter, rounded, emerge from the proximal compartment and synapse with climbing fibers. Different culture models and mutant mice analyses suggest the identification of intrinsic versus extrinsic determinants of the Purkinje cell dendritic development. The early phase of dendritic remodeling might be cell autonomous and regulated by specific transcription factors such as retinoid-related orphan receptor alpha (RORalpha). Afferent fibers, trophic factors and hormones regulate the orientation and growth of the mature dendritic tree contributing, with still unknown intrinsic factors, to sculpt its general architecture. The formation of spines appears as an intrinsic phenomenon independent of their presynaptic partner, the parallel fibers, and confined to the distal compartment by inhibitory influences of the climbing fibers along the proximal compartment.

Regional brain variations of cytochrome oxidase activity and motor coordination in Girk2Wv (Weaver) mutant mice

The Girk2(Wv) (weaver) phenotype, caused by a mutated inward rectifying potassium channel, is characterized by degeneration of cerebellar granule cell population as well as midbrain dopamine-containing cells of the nigrostriatal pathway. To investigate the regional brain metabolic consequences of this combined pathology, cytochrome oxidase (CO) activity was measured by histochemistry from brain regions of wild-type and homozygous Girk2(Wv) mutant mice and correlated with motor performances. CO activity of Girk2(Wv) mutants was abnormal in cerebellar cortex, dentate nucleus, and brainstem regions (medial and lateral vestibular nuclei, prepositus, superior colliculus, lateral cuneiform nucleus, and reticular nuclei) implicated in the gaze system. CO activity increased in midbrain dopaminergic regions after correcting for tissue density, regions with severe depletion of tyrosine hydroxylase activity. Forebrain regions were relatively spared in term of CO activity, except for subthalamic nucleus, lateral geniculate nucleus, and cortical eye field. Similarly to the Rora(sg) cerebellar mutant, metabolic alterations in cerebellar and vestibular regions were linearly correlated with poor motor coordination, underlining the sensitivity of these tests to cerebellar dysfunction.

Spontaneous and induced mouse mutations with cerebellar dysfunctions: behavior and neurochemistry

Grid2(Lc) (Lurcher), Grid2(ho) (hot-foot), Rora(sg) (staggerer), nr (nervous), Agtpbp1(pcd) (Purkinje cell degeneration), Reln(rl) (reeler), and Girk2(Wv) (Weaver) are spontaneous mutations with cerebellar atrophy, ataxia, and deficits in motor coordination tasks requiring balance and equilibrium. In addition to these signs, the Dst(dt) (dystonia musculorum) spinocerebellar mutant displays dystonic postures and crawling. More recently, transgenic models with human spinocerebellar ataxia mutations and alterations in calcium homeostasis have been shown to exhibit cerebellar anomalies and motor coordination deficits. We describe neurochemical characteristics of these mutants with respect to regional brain metabolism as well as amino acid and biogenic amine concentrations, uptake sites, and receptors.

Fine structure of neuronal and glial processes in neuropathology

The cells of the nervous system are characterized by their well-formed cell processes and by cell-to-cell relationships that they form. The neuron reveals essentially cylindrical processes, which form synaptic junctions. On the other hand, the peripheral parts of the glial cells are mainly sheet-like in nature. Thus, the oligodendroglial cell elaborates many sheet-like processes, each of which forms a segment of the myelin sheath. Unique cell junction, transverse bands are present at the interface of oligodendroglial processes and the axon. Finally, the astrocytes also form elaborate sheet-like processes, which separate most of the CNS from the mesodermal tissue as well as surrounding certain neuronal surfaces, including synapses. Punctate adhesions, gap junctions and other adhesive devices are present between astrocytic processes. Defects or anomalies in the neuronal and glial cell processes characterize numerous pathological conditions.

Patterned Purkinje cell death in the cerebellum

The object of this review is to assemble much of the literature concerning Purkinje cell death in cerebellar pathology and to relate this to what is now known about the complex topography of the cerebellar cortex. A brief introduction to Purkinje cells, and their regionalization is provided, and then the data on Purkinje cell death in mouse models and, where appropriate, their human counterparts, have been arranged according to several broad categories--naturally-occurring and targeted mutations leading to Purkinje cell death, Purkinje cell death due to toxins, Purkinje cell death in ischemia, Purkinje cell death in infection and in inherited disorders, etc. The data reveal that cerebellar Purkinje cell death is much more topographically complex than is usually appreciated.

N-myc is essential during neurogenesis for the rapid expansion of progenitor cell populations and the inhibition of neuronal differentiation

To address the role of N-myc in neurogenesis and in nervous system tumors, it was conditionally disrupted in neuronal progenitor cells (NPCs) with a nestin-Cre transgene. Null mice display ataxia, behavioral abnormalities, and tremors that correlate with a twofold decrease in brain mass that disproportionately affects the cerebellum (sixfold reduced in mass) and the cerebral cortex, both of which show signs of disorganization. In control mice at E12.5, we observe a domain of high N-Myc protein expression in the rapidly proliferating cerebellar primordium. Targeted deletion of N-myc results in severely compromised proliferation as shown by a striking decrease in S phase and mitotic cells as well as in cells expressing the Myc target gene cyclin D2, whereas apoptosis is unaffected. Null progenitor cells also have comparatively high levels of the cdk inhibitors p27(Kip1) and p18(Ink4c), whereas p15(Ink4b), p21(Cip1), and p19(Ink4d) levels are unaffected. Many null progenitors also exhibit altered nuclear morphology and size. In addition, loss of N-myc disrupts neuronal differentiation as evidenced by ectopic staining of the neuron specific marker betaTUBIII in the cerebrum. Furthermore, in progenitor cell cultures derived from null embryonic brain, we observe a dramatic increase in neuronal differentiation compared with controls. Thus, N-myc is essential for normal neurogenesis, regulating NPC proliferation, differentiation, and nuclear size. Its effects on proliferation and differentiation appear due, at least in part, to down-regulation of a specific subset of cyclin-dependent kinase inhibitors.

Cytodifferentiation of Bergmann glia and its relationship with Purkinje cells

The Bergmann glia is composed of unipolar protoplasmic astrocytes in the cerebellar cortex. Bergmann glial cells locate their cell bodies around Purkinje cells, and extend radial or Bergmann fibers enwrapping synapses on Purkinje cell dendrites. During development, Bergmann fibers display a tight association with migrating granule cells, from which the concept of glia-guided neuronal migration has been proposed. Thus, it is widely known that the Bergmann glia is associated with granule cells in the developing cerebellum and with Purkinje cells in the adult cerebellum. As the information on how Bergmann glial cells are related structurally and functionally with differentiating Purkinje cells is quite fragmental, this issue has been investigated using cytochemical techniques for Bergmann glial cells. This review classifies the cytodifferentiation of Bergmann glial cells into four stages, that is, radial glia, migration, transformation and protoplasmic astrocytes, and then summarizes their structural relationship with Purkinje cells at each stage. The results conclude that the cytodifferentiation of Bergmann glial cells proceeds in correlation with the migration, dendritogenesis, synaptogenesis and maturation of Purkinje cells. Furthermore, morphological and molecular plasticity of this neuroglia appears to be regulated depending on the cytodifferentiation of nearby Purkinje cells. The functional relevance of this intimate neuron-glial relationship is also discussed with reference to recent studies in cell biology, cell ablation and gene knockout.

Mutant mice as a model for cerebellar ataxia

Not later than two synapses after their arrival in the cerebellar cortex all excitatory afferent signals are subsequently transformed into inhibitory ones. Guaranteed by the exceedingly ordered and stereotyped synaptic arrangement of its cellular elements, the cerebellar cortex transmits this inhibitory result of cerebellar integration exclusively via Purkinje cells (PCs) in a precise temporal succession directly onto the target neurons of the deep cerebellar and vestibular nuclei. Thus the cerebellar cortex seems to produce a temporal pattern of inhibitory influence on these target neurons that modifies their excitatory action in such a way that an activation of muscle fibers occurs which progressively integrates the intended motion into the actual condition of the motoric inventory. In consequence, disturbances that affect this cerebellar inhibition will cause uncoordinated, decomposed and ataxic movements, commonly referred to as cerebellar ataxia. Electrophysiological investigations using different cerebellar mouse mutants have shown that alterations in the cerebellar inhibitory input in the target nuclei lead to diverse neuronal responses and to different consequences for the behavioural phenotype. A dependence between the reconstitution of inhibition and the behavioural outcome seems to exist. Obviously two different basic mechanisms are responsible for these observations: (1) ineffective inhibition on target neurons by surviving PCs; and (2) enhancement of intranuclear inhibition in the deep cerebellar and vestibular nuclei. Which of the two strategies evolves is dependent upon the composition of the residual cell types in the cerebellum and on the degree of PC input loss in a given area of the target nuclei. Motor behaviour seems to deteriorate under the first of these mechanisms whereas it may benefit from the second. This is substantiated by stereotaxic removal of the remaining PC input, which eliminates the influence of the first mechanism and is able to induce the second strategy. As a consequence, motor performance improves considerably. In this review, results leading to the above conclusions are presented and links forged to human cerebellar diseases.

Down-regulated expression of glutamate transporter GLAST in Purkinje cell-associated astrocytes of reeler and weaver mutant cerebella

The glutamate transporter plays an important role in rapid removal of glutamate from the synaptic cleft. Glutamate transporter GLAST is highly expressed in the Bergmann glia (BG), a unipolar cerebellar astrocyte associated structurally and functionally with Purkinje cells (PCs). Here we investigated the expression and localization in the reeler and weaver mutant cerebella with disorganized cytoarchitecture and disrupted synaptic circuitry. In the cortex of both cerebella, GLAST-expressing cells were astrocytes associating PCs; they were located around PC somata and primary dendrites, and extended glial fibrillary acidic protein (GFAP)-immunopositive processes surrounding PC somata and dendrites. Additional signals were detected in astrocytes of the reeler subcortex; they were dispersed among ectopic PCs and had GFAP-positive processes apposing to PC somata and stunted dendrites. Therefore, GLAST expression in PC-associated astrocytes was conserved in these mutants. Compared to the wild-type BG, however, the transcription level in individual mutant astrocytes was significantly reduced to about one-third level in the reeler and weaver cortex or one-sixth level in the reeler subcortex. Taking previous results on remarkable up-regulation during dendritogenic/synaptogenic stages and down-regulation following experimental glutamatergic denervation, it is suggested that GLAST expression in cerebellar astrocytes is regulated correlatively with cytological and/or synaptic differentiation of neighboring PCs.

Grooming in Lurcher mutant mice

Lurcher mutant mice, characterized by degeneration of cerebellar Purkinje cells and granule cells, were compared to normal littermate controls for different facets of grooming and nongrooming behaviors after a brief period of water immersion. By comparison to normal controls, the number and the duration of several grooming components were decreased in Lurcher mutant mice, namely, licking the forelimb, the abdomen, the back, and the hindlimb. By contrast, the number and duration of body-shaking episodes were not reduced. Lurcher mutants had fewer grooming elements for bouts with at least five elements. However, the serial organization of grooming, as determined by the order of appearance of grooming elements, was maintained in Lurcher mutants. These results indicate that the cerebellar cortex is involved in the appearance of various grooming elements but not in the organization of the cephalocaudal sequence.

Impaired parallel fiber-->Purkinje cell synapse stabilization during cerebellar development of mutant mice lacking the glutamate receptor delta2 subunit

The glutamate receptor delta2 subunit (GluRdelta2) is specifically expressed in cerebellar Purkinje cells (PCs) from early developmental stages and is selectively localized at dendritic spines forming synapses with parallel fibers (PFs). Targeted disruption of the GluRdelta2 gene leads to a significant reduction of PF-->PC synapses. To address its role in the synaptogenesis, the morphology and electrophysiology of PF-->PC synapses were comparatively examined in developing GluRdelta2 mutant and wild-type cerebella. PCs in GluRdelta2 mutant mice were normally produced, migrated, and formed spines, as did those in wild-type mice. At the end of the first postnatal week, 74-78% of PC spines in both mice formed immature synapses, which were characterized by small synaptic contact, few synaptic vesicles, and incomplete surrounding by astroglial processes, eliciting little electrophysiological response. During the second and third postnatal weeks when spines and terminals are actively generated, the percentage of PC spines forming synapses attained 98-99% in wild type but remained as low as 55-60% in mutants, and the rest were unattached to any nerve terminals. As a result, the number of PF synapses per single-mutant PCs was reduced to nearly a half-level of wild-type PCs. Parallelly, PF stimulation less effectively elicited EPSCs in mutant PCs than in wild-type PCs during and after the second postnatal week. These results suggest that the GluRdelta2 is involved in the stabilization and strengthening of synaptic connectivity between PFs and PCs, leading to the association of all PC spines with PF terminals to form functionally mature synapses.

Impaired parallel fiber-->Purkinje cell synapse stabilization during cerebellar development of mutant mice lacking the glutamate receptor delta2 subunit

The glutamate receptor delta2 subunit (GluRdelta2) is specifically expressed in cerebellar Purkinje cells (PCs) from early developmental stages and is selectively localized at dendritic spines forming synapses with parallel fibers (PFs). Targeted disruption of the GluRdelta2 gene leads to a significant reduction of PF-->PC synapses. To address its role in the synaptogenesis, the morphology and electrophysiology of PF-->PC synapses were comparatively examined in developing GluRdelta2 mutant and wild-type cerebella. PCs in GluRdelta2 mutant mice were normally produced, migrated, and formed spines, as did those in wild-type mice. At the end of the first postnatal week, 74-78% of PC spines in both mice formed immature synapses, which were characterized by small synaptic contact, few synaptic vesicles, and incomplete surrounding by astroglial processes, eliciting little electrophysiological response. During the second and third postnatal weeks when spines and terminals are actively generated, the percentage of PC spines forming synapses attained 98-99% in wild type but remained as low as 55-60% in mutants, and the rest were unattached to any nerve terminals. As a result, the number of PF synapses per single-mutant PCs was reduced to nearly a half-level of wild-type PCs. Parallelly, PF stimulation less effectively elicited EPSCs in mutant PCs than in wild-type PCs during and after the second postnatal week. These results suggest that the GluRdelta2 is involved in the stabilization and strengthening of synaptic connectivity between PFs and PCs, leading to the association of all PC spines with PF terminals to form functionally mature synapses.

Distribution of metabotropic glutamate receptor type 1a in Purkinje cell dendritic spines is independent of the presence of presynaptic parallel fibers

The metabotropic glutamate receptor type 1a (mGluR1a) is expressed at a high level in the molecular layer of the cerebellar cortex, where it is localized mostly in dendritic spines of Purkinje cells, innervated by parallel fibers. Treatment with methylazoxymethanol (MAM) of mouse pups at postnatal days (PND) 0 + 1 or 5 + 6 results in the partial loss of granule cells, the extent of which depends on the age of the animal at the time of injection. As a consequence of hypogranularity, the number of parallel fibers is decreased to such an amount that many of the postsynaptic Purkinje cell dendritic spines are devoid of axonal input, and only a limited number of spines participate in the formation of parallel fiber synapses, or, infrequently, in heterologous or heterotopic synapses with other presynaptic partners. At PND 30, 50% of the spines in the cerebella of mice treated with MAM at PND 0 + 1 was not contacted by any presynaptic element, compared to 5% in controls or 15% in the cerebella of mice treated with MAM at PND 5 + 6. The localization of mGluR1a was visualized by immunocytochemistry on ultrathin sections: approximately 80% of all Purkinje cell dendritic spines were immunopositive in controls and in both groups of MAM-treated mice, indicating that mGluR1a was present in Purkinje dendritic spines even when the corresponding synaptic input was absent. This observation indicates that the expression and subcellular distribution of mGluR1a are inherent, genetically determined properties of Purkinje cells.

Visuospatial abilities

The importance of the hippocampus and its anatomical connections, including the medial septum, thalamic nuclei, and neocortical regions in many spatial tasks including the Morris water maze, has been emphasized. Studies in mutant mice with cerebellar atrophy and in rats with electrolytic lesions of the cerebellum have indicated that the cerebellum has a role in visuospatial and visuomotor processes in the Morris maze. Directional deficits in the water have also been noted in rats whose cerebellum was exposed to X-rays during different developmental stages. Cerebellar interactions with the superior colliculus, the hippocampus, and the neocortex via thalamic nuclei are suggested to be the basis of the cerebellar modulation of directional sense in maze tests.

Serial changes in granuloprival cerebellar cultures after transplantation with granule cells and glia: a timed ultrastructural study

Granuloprival cerebellar cultures derived from neonatal mice were transplanted at nine days in vitro with granule cells and glia, and the changes induced in the host explants were examined daily with the electron microscope from one to nine days post-transplantation. Granule cells and astrocytes had migrated into the host cultures within 24 h, and astrocytic processes began to ensheath Purkinje cells and to interpose themselves between axon terminals and Purkinje cell somata, reducing the number of axosomatic synapses. Occasional degenerating Purkinje cells were present. At two days post-transplantation, synapse formation between parallel fibre terminals and Purkinje cell dendritic spines was initially evident, and Purkinje cells began to proliferate dendritic spines near astrocytic processes. Degenerating Purkinje cells were more frequently encountered. Myelin was first observed in host cultures at three days after transplantation, and astrocytes continued to ensheath Purkinje cells and reduce the population of axosomatic synapses, a process that began to stabilize at four days post-transplantation. At this time astrocytic ensheathment had extended to Purkinje cell dendrites and dendritic spine synapses. Proliferation of Purkinje cell dendritic spines accelerated, and occasional synapses with presumptive parallel fibre terminals were present among clusters of proliferated spines. At five days after transplantation, contours of Purkinje cells were rounded, and there was a decrease of somatic spines and of synapses with somatic spines. Purkinje cells were fully ensheathed by astrocytic processes by six days post-transplantation and had assumed a mature appearance. Homotypical parallel fibre-Purkinje cell dendritic spine synapses were predominant in more developed areas of cortical neuropil as heterotypical recurrent axon collateral-Purkinje cell dendritic spine synapses were reduced. Increasing synapse formation was evident among clusters of proliferated spines, which continued at seven days post-transplantation, as the spine clusters became less frequent. At eight days after transplantation, space between Purkinje cells had increased and the cortical neuropil resembled that of comparably aged control cultures. Occasional degenerating Purkinje cells were still evident at nine days post-transplantation, at which time residual clusters of proliferated unattached dendritic spines were scarce. The sequence of changes after transplantation was consistent with the specific roles of the transplanted elements. Astrocytes were involved with the regulation of synapse density, including reduction of some heterotypical synapses, and induced proliferation of Purkinje cell dendritic spines. Granule cell axons synapsed with Purkinje cell dendritic spines, further reducing heterotypical synapses and restoring cortical circuitry to a near control state. The loss of heterotypical synapses was associated with programmed cell death of excess Purkinje cells, reducing the Purkinje cell population to control levels.

Altered intracellular localization of the glutamate receptor channel delta 2 subunit in weaver and reeler Purkinje cells

The glutamate receptor (GluR) channel delta 2 subunit is expressed abundantly and specifically in cerebellar Purkinje cells. Our previous study demonstrated that the GluR is expressed as early as embryonic day 15 prior to Purkinje cell synaptogenesis, and its protein product accumulates in dendritic spines during normal Purkinje cell maturation. In this study, we examined expression and distribution of the GluR delta 2 in the weaver and reeler mutant cerebelli, which show abnormal cytoarchitecture and neural circuitry. In situ hybridization analysis showed that GluR delta 2 mRNA was expressed in entire Purkinje cells in both mutant mice. Immunohistochemical analysis revealed that intracellular localization of GluR delta 2 was altered in some region of mutant cerebelli. In the cortical surface where Purkinje cells from synapses with parallel fibers, GluR delta 2-immunoreactivity was restricted to dendritic spines of Purkinje cells as observed in normal mice. In contrast, in the subcortical region where granule cells and parallel fibers are absent, the immunoreactivity was found widely in Purkinje dendrites. Thus, the GluR delta 2 protein did not accumulate to the dendritic spines of Purkinje cells lacking synaptic contact with parallel fibers. These results suggest that the expression of both GluR delta 2 mRNA and protein is independent of abnormalities in the mutant cerebelli, but relocalization of the GluR delta 2 protein might depend on the formation of synapses between Purkinje cells and parallel fibers.

Neural plasticity in cerebellar cultures

Cerebellar granule cells and oligodendrocytes are destroyed and astrocytes are functionally compromised by exposure of organotypic cerebellar cultures derived from newborn mice to cytosine arabinoside for the first 5 days in vitro. Consequently, myelin does not form and Purkinje cells survive in increased numbers, but without astrocytic ensheathment. In the absence of glial sheaths, Purkinje cells have altered membrane properties and reduced input resistance. Their inhibitory recurrent axon collaterals sprout enormously and hyperinnervate the unensheathed somata of other Purkinje cells and form heterotypical synapses with Purkinje cell dendritic spines normally occupied by homotypical excitatory parallel fiber (granule cell axon) terminals. This reorganization of the cortical circuitry, in which recurrent axon collaterals are the dominant inhibitory elements, allows retention of some inhibition in the absence of parallel fiber excitation of the inhibitory interneurons. In the absence of neuronal activity, the full complement of inhibitory synapses is not developed and the cultures exhibit sustained cortical hyperactivity after recovery from the blockade. If granule cells and glia are replaced, a second round of reorganization ensues, in the direction of restoration of the normal cortical circuitry. The cultures are myelinated and the number of recurrent axon collaterals is reduced. Astrocytes ensheath Purkinje cell somata and strip excess axosomatic synapses, as well as eliminate some of the heterotypical synapses in the cortical neuropil. Parallel fibers synapse with already present Purkinje cell dendritic spines and with newly proliferated spines, the latter induced by an astrocyte secreted factor. As homotypical synapses develop and heterotypical synapses decline, Purkinje cells undergo apoptosis and their population is reduced to control levels. With the restoration of parallel fiber excitation, recurrent axon collaterals are no longer the dominant cortical inhibitory elements. If neuronal activity is blocked as the granule cells and glia are replaced, there is incomplete formation of inhibitory synapses, and cortical discharges are hyperactive after recovery from activity blockade.

Altered IGFBP5 gene expression in the cerebellar external germinal layer of weaver mutant mice

The IGF system components play important roles in cerebellar development as demonstrated by their specific spatial-temporal expression. IGF-I, type I IGF receptor (IGFR-I), IGFBP2 and IGFBP5 mRNA are localized in distinct cell populations, and all are expressed at the highest levels at the peak of Purkinje cell growth, active synaptogenesis and dendritic formation. To understand IGF-I's action at the cellular level, in situ hybridization was employed to investigate the distribution of IGF system gene transcripts in the cerebellum of weaver mutant mice (wv/wv). Although located ectopically, the surviving Purkinje cells express IGF-I mRNA at the same level in wv/wv as in +/+. No alteration in the cellular distribution or mRNA levels was observed with IGFBP2, or IGFR-I mRNAs. However, the pattern of IGFBP5 expression is altered in the external germinal layer of wv/wv mice. Not only is IGFBP5 expressed by more granule cell precursors of wv/wv cerebellum, but its mRNA level is 2.3 fold that of +/+. The altered IGFBP5 gene expression in granule cell precursors may modulate the interaction of IGF-I with IGFR-I in ways that contribute to their massive death occurring in the development of wv/wv cerebellum.

Cerebellar contributions to instrumental learning

There is emerging evidence that the cerebellum is involved in spatial and nonspatial instrumental learning tasks. Cerebellar-lesioned animals have deficits in water maze learning tasks that may be explained by two-way interactions with higher order brain regions. There is suggestive evidence that cerebellar modulation extends to shock avoidance and discrimination learning. Although this evidence needs to be confirmed by a wider range of lesion methods and choice of learning tasks, it is in line with the hypothesis that the cerebellum affects cognitive processes and is not strictly concerned with motor control and the acquisition and retention of conditioned reflexes.

Histopathological study on cerebellar dysgenesis of shaking rat Kawasaki (SRK)

The cerebellum of shaking rat Kawasaki (SRK) was studied histochemically and immunocytochemically. The cerebellar cortex was characterized by a delay in the disappearance of the external granular layer, a narrow molecular layer, a narrow and cell sparse internal granular layer, and disarranged and heterotopically situated Purkinje cells with tortuous arborization and a large cell cluster in the depths of the cerebellum. Golgi-Cox staining revealed an abnormal ramification and polarity of ectopic Purkinje cells. Ultrastructurally, most spines of Purkinje cells in the depths remained naked. Based on these results, it is suggested that the genetically determined mechanisms responsible for the abnormal structure in the cerebellar cortex of SRK may include a migratory disorder of the Purkinje cells, and a decrease in the microneurons with a resulting decrease of synaptic contacts on the Purkinje cell soma and dendrite.

Membrane structure of parallel-fibre synaptic terminals in the cerebellum of the jaundiced Gunn rat: freeze-fracture and E-PTA study

Parallel-fibre synaptic membranes were examined by freeze-fracture and ethanolic-phosphotungstic acid methods in the cerebellum of homozygous (j/j) Gunn rats with hereditary jaundice. Parallel-fibre synapses with dendritic spines of Purkinje cell were severely affected since many Purkinje cells degenerated during the early postnatal period. Some parallel-fibre synaptic terminals lacked their postsynaptic partners and faced astrocytic processes from 18 days of age to the adult stage. These parallel-fibre terminals contained clusters of synaptic vesicles adjacent to synaptic membranes, and synaptic membranes and synaptic cleft materials were identical to those of parallel fibres with postsynaptic partners, as visualized by conventional electron microscopy with osmium tetroxide postfixation and staining of sections with uranyl acetate and lead citrate. In freeze-fractured specimens, the presynaptic membrane of parallel fibres had diffusely distributed large particles and tiny pits on the P-face and protuberances on the E-face, together representing synaptic vesicle attachment sites. Such vesicle attachment sites were present on the presynaptic membranes of parallel fibres without postsynaptic partners from day 18 to the adult stage. After ethanolic-phosphotungstic acid staining, parallel-fibre terminals displayed presynaptic dense projections, intercleft materials and postsynaptic thickening, but some parallel fibres lacked postsynaptic thickening. These observations suggest that the presynaptic membrane structure of the parallel fibre is preserved, even in the absence of a postsynaptic partner, in j/j cerebella. A mechanism for persistence of presynaptic membrane structures without postsynaptic partners in j/j cerebella is discussed.

Neurological dysfunction expressed in the grooming behavior of developing weaver mutant mice

The present study provides the first quantitative developmental analysis of movement in the weaver (wv/wv) mutant mouse. This autosomal recessive mutation affects both striatal and cerebellar circuitries that are related to motor performance. We report data on post-swim grooming behavior in 14 mutant and 14 control animals on alternate postnatal Days 13-20. Mutant animals showed a greater number, but shorter duration, of grooming bouts across this developmental period. The mutant animals also used external support during grooming, expressed various forms of ataxia, performed a higher proportion of smaller forelimb strokes than did the control animals, and failed to complete as many full stereotypic grooming sequences. These differences between mutant and control animals followed distinctive developmental courses. Our data demonstrate that previous anatomical and physiological characterizations of the weaver mutation have overt motor correlates.

The olivocerebellar projection in normal (+/+), heterozygous weaver (wv/+), and homozygous weaver (wv/wv) mutant mice: comparison of terminal pattern and topographic organization

Olivocerebellar organization and topography were analyzed in adult normal (+/+), heterozygous weaver (wv/+), and homozygous weaver (wv/wv) mutant mice. The two genotypes (wv/+ and wv/wv) of the weaver mutant present a gradation of abnormal cerebellar morphology. Purkinje cell (PC) ectopia ranges from mild (wv/+) to moderate (wv/wv), and regional PC loss is also graded in the two types. To determine olivocerebellar organization and topography, tritiated amino acids were placed into different regions of the inferior olivary complex (IO) in normal, heterozygous, and homozygous weaver mice. Despite some PC loss and ectopia, olivocerebellar fiber (OCF) terminals in both homozygous and heterozygous weaver mice have an orthogonal distribution and topography similar to that seen in normal mice. Differences in OCF termination, such as an increased density of OCF terminal label in the lower portion of the molecular layer, the PC, and granule cell layers, are seen in homozygous weaver mice. In some heterozygous weaver and normal cases, multiple injections labeling most IO cells on one side of the IO resulted in continuous OCF terminal labeling in many regions of the contralateral cerebellar cortex, suggesting that all PCs receive OCF input. Retrograde analysis involving injections of horseradish peroxidase conjugated to wheat germ agglutinin into different mediolateral cerebellar regions in homozygous weaver mice further demonstrates a generally normal olivocerebellar topography.

The distribution of dystrophin in the murine central nervous system: an immunocytochemical study

A mild non-progressive cognitive defect is a feature of the fatal X-linked disease, Duchenne muscular dystrophy. Recent studies have identified the genetic defect and the resulting loss of the protein dystrophin, and shown that dystrophin messenger RNA and protein are present in normal brain tissue. We have performed western immunoblotting and fluorescence immunocytochemistry using a sensitive antibody made against a large fragment of the dystrophin molecule to study the regional, cellular and subcellular distribution of dystrophin in the mammalian brain. The brains of B10 (control) and mdx (dystrophin deficient null mutant) mouse brain were compared on a point-by-point basis to verify that only dystrophin and not autosomal dystrophin related protein or cross-reacting proteins were being identified. In addition three murine neurologic mutants, nervous, lurcher, and weaver, were studied to refine the localization of dystrophin. In western immunoblots, dystrophin is present in all regions of the brain and in greatest abundance in the cerebellum. Dystrophin, as demonstrated in immunofluorescence, is present in neurons, but not in glia or myelin, and forms punctate foci associated with the plasma membrane of perikarya and dendrites, but not axons. While dystrophin is abundant in cerebral cortical neurons and cerebellar Purkinje cells, it is absent from most subcortical neurons, the granule cells of fascia dentata, and cerebellar neurons other than Purkinje cells. The absence of dystrophin in the cerebellum of the Purkinje cell deficient mutants nervous and lurcher, and its presence in the granule cell deficient mutant weaver indicate that dystrophin is a component of Purkinje cells rather than closely apposed afferents to those cells. The distribution and localization of dystrophin suggests a role in organizing the plasma membrane, possibly as an anchor of the postsynaptic apparatus, a possible basis for the cognitive defect in Duchenne dystrophy.

Plasticity of GABAergic terminals in Deiters' nucleus of weaver mutant and normal mice: a quantitative light microscopic study

This study reports on the developmental changes in size and the average density of GABAergic axonal boutons bordering on the somata of large neurons in the dorsal part of the lateral vestibular nucleus (Deiters' nucleus) in normal and mutant mice. Weaver mutants, PCD mutants and the corresponding wild types were used to test for size alterations and differences in the number of GABA-immunopositive terminals. Hemicerebellectomized animals were examined in addition. Quantification of bouton profile size was performed from 30-microns-thick vibratome and 0.5-micron Araldite-embedded semi-thin sections immunoreacted for GABA from 7 days postnatally up to an age of 9 months. Terminal density was determined at the 5-6 month stage from semi-thin sections only. Morphometric analysis over the lifetime of normal animals (B6CBA) revealed a progressive increase in the size of bouton profiles, which peaked at 5-6 months and reached sizes of 2-3 microns2. In weaver mutants a parallel development in terminal size was found to be present, but the size of the largest terminals exceeded those of the controls by 75-100%, reaching 3-6 microns2 with the same time course. PCD mutants, with an almost total absence of Purkinje cells had, on the contrary, small bouton profiles that reached a maximum of only 2 microns2. The hemicerebellectomized animals responded with decreased bouton profile size ipsilaterally. The terminal numbers per unit membrane length were surprisingly similar in wild types and weaver mutants, despite a reduction in Purkinje cells of almost 50% in the weaver anterior lobe.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic and age related models of neurodegeneration in mice: dystrophic axons

Dystrophic axons (DA) are non-specific lesions that occur in a wide variety of human and animal diseases. In this paper we describe the distribution of these lesions in three newly discovered mouse neurological mutants. The distribution of DA in these mutants is defined by their names, lumbosacral neuroaxonal dystrophy (lnd), located on Chromosome 7, generalized neuroaxonal dystrophy (gnd) and vestibulomotor degeneration (vmd). The last mutant, which has degeneration as well as DA in lateral vestibular nucleus and vestibulo-spinal tracts, dies in the first weeks of life; the first two live for approximately one year. A previously described mutation, dystonia musculorum (dt), was found to produce generalized DA like gnd, but dt/dt mutants die at an early age. DA were also found to occur in the nuclei gracilis and cuneatus, in the area of Clark's column and in lumbo-sacral spinal cord in aging normal mice either fed ad libitum or at a level of 40% dietary restriction. The dietary regimen had little effect on the numbers of DA observed in susceptible areas of the neuroaxis. The mutant models of neuroaxonal dystrophy may prove useful in studies of the pathophysiology of DA in general and of specific inherited diseases of man, such as infantile neuroaxonal dystrophy and Hallervordin-Spatz disease.

Sequential events of degeneration and synaptic remodelling in the viper optic tectum following retinal ablation. A degeneration, radioautographic and immunocytochemical study

The ultrastructural changes taking place in the retino-recipient layers of the viper optic tectum were examined between 5 and 122 days after retinal ablation. The initial degeneration of retinotectal terminals proceeds at widely different rates and is characterized by a marked degree of polymorphism in which a number of different patterns can be discerned. In the final stages of degeneration, either both the degenerating bouton and the distal portion of the postsynaptic element are engulfed by reactive glia, or, more frequently, only the degenerating terminal is eliminated and the postsynaptic differentiation remains. The free postsynaptic differentiations are reoccupied predominantly by boutons containing pleiomorphic vesicles and which are for the most part gamma-aminobutyric acid (GABA)ergic, thus forming heterologous synapses; less frequently these sites are occupied by boutons of the ipsilateral visual contingent to form homologous synapses. These two processes, both of which depend on terminal axonal sprouting, take place within the first 3 postoperative months. They are followed by a decrease in the number of heterologous synapses and a concurrent increase in the number of homologous synapses newly formed by optic boutons generated by collateral preterminal sprouting of ipsilateral retinotectal fibres. The data suggest that partial deafferentation of the optic tectum induces a transitory GABAergic innervation of free postsynaptic sites prior to the restoration of new retinal synaptic contacts.

Altered excitatory amino acid function and morphology of the cerebellum of the spastic Han-Wistar rat

A mutant strain of Han-Wistar rat carries an autosomal recessive gene producing spastic paresis which is characterized by ataxia, tremor and hind limb rigidity. Brains of affected rats and unaffected littermate controls were transected at the mesencephalon into rostral and caudal portions (the caudal portion contained the cerebellum and brainstem). Poly(A)+ mRNA was isolated from pooled rostral or caudal portions and injected into Xenopus oocytes. The oocytes were voltage-clamped and exposed to 1 mM L-glutamate, 500 microM kainate, 500 microM quisqualate, 200 microM N-methyl-D-aspartate (NMDA) or 1 mM gamma-aminobutyric acid (GABA). Oocytes injected with mRNA isolated from the caudal portions of the affected rat brains exhibited statistically significant increases in glutamate and kainate peak current responses compared to oocytes injected with mRNA from other brain samples. No differences were noted in the responses of the groups when exposed to quisqualate, NMDA or GABA. Cerebellar and brain stem mRNA were also isolated separately in different groups of mutants and unaffected littermates. Only oocytes injected with cerebellar mRNA from mutants displayed statistically significant increases in responses to glutamate and kainate. In parallel morphological studies changes in the cerebellum of mutants were also observed. These consisted of a loss of Purkinje cells and an asymmetrical disarrangement of the granule cell layer of cerebellar cortex. Taken together, the physiological and morphological results suggest that alterations in glutamate/kainate receptors in the cerebellum are phenotypic manifestations of the Han-Wistar mutation. The results are consistent with the hypothesis that this mutant rat might serve as a model of glutamate/kainate excitotoxicity in the brain.

Vestibular pathology in a new-mutant mouse

The histological characteristics of the vestibule in a strain of new-mutant mice were studied under light microscopy. These new-mutant mice, manifesting drawing back, circling, head-tossing and hyperactive behavior arose as a spontaneous mutation in the C3H/He stock. For our study, 36 of these mice ranging in age from 10 days to 18 months were used. At 10 to 15 days after birth, the vestibular gross anatomy was well-developed and all three cristae and two maculae were morphologically normal. Age-dependent degeneration of the saccular maculae was found to begin at 21 days, and almost all hair cells were missing at 90 days. Further, morphological changes in the utricular maculae appeared at one year, and a severe loss of hair cells was observed at 18 months. In contrast, the cristae ampullaris remained well preserved until the age of 18 months. The phenotype of the abnormal gene in these mutant mice correlates to the morphological abnormalities seen in the vestibule.

An ultrastructural study on vestibular sensory cells in a new-mutant mouse

The ultrastructural characteristics of the vestibular epithelium and light microscopical study of the central nervous system of a strain of new-mutant mice were analyzed. For the vestibular study, we used 72 homozygotes with ages ranging from 10 days to 18 months. The most striking findings observed in these mice were the disarray of the stereocilia of the utricular and saccular maculae and disintegration of the saccular otoconia. Many hair cells displayed abnormality of the stereocilia such as reduced number, disorganized distribution, and giant cilia, although the hair cell cytoplasm, including the nerve terminals, became fully developed. Demineralization of the saccular otoconia was age dependent, and a complete loss of the saccular hair cells was demonstrated. In conjunction with the disarray of the outer hair cells of the cochlea, morphological manifestation of the gene abnormality of these mice was related to immaturation of the stereociliary tufts. Because no morphological abnormality was observed in the central nervous system, the abnormal behavior in these mice was primarily correlated with morphological abnormalities of the vestibule.

Unique cerebellar phenotype combining granule and Purkinje cell loss: morphological evidence for weaver* pcd double mutant mice

Weaver (wv/wv) mutant mice lose most granule cells of the cerebellum during the first 2 weeks of postnatal life; 'Purkinje cell degeneration' (pcd/pcd) mutants lose virtually all Purkinje cells between postnatal days 17 and 45. Both these neurological mutations are autosomal recessive. We designed a breeding protocol that, in theory, should result in the production of mice with a doubly mutant, wv/wv*pcd/pcd, genotype. Some of the offspring of such crosses had a novel cerebellar phenotype in which both granule and Purkinje cells underwent degeneration, leading to a highly atrophic cortex. This phenotype is what would be expected in wv/wv*pcd/pcd double mutants, and the proportion of such progeny obtained fits with genetic expectations. We propose that (1) wv/wv*pcd/pcd double mutant mice are viable, and (2) the anatomical phenotype of such mice is a combined expression of the component phenotypes.

Interleukin-1 hyperproduction by in vitro activated peripheral macrophages from cerebellar mutant mice

Several mutations in mice produce complex patterns of neuronal degeneration of the cerebellum and of its afferent pathways. In the staggerer (sg/sg) mutant, atrophy of the lymphoid organs and immunological abnormalities have been described. To search for a possible link between the neurological and the immune disorders in this mutant, we studied the production by its peripheral macrophages of interleukin-1 (IL-1), which roles in both immune and nervous systems are well established. Suspensions of peritoneal and/or spleen macrophages from mutants and their appropriate controls were stimulated in vitro by lipopolysaccharide. Northern and dot blots, performed with murine IL-1 cDNA probes, revealed a clear-cut hyperexpression of IL-1 mRNA in staggerer macrophages. An IL-1 bioassay using the IL-1-responsive D10.G4 cell line also revealed a sixfold increase of IL-1 activity in the macrophage supernatants of staggerer mutant mice. The hyperproduction was found in 3-week to 1-year-old staggerer and also in heterozygous (+/sg) mice. A similar phenomenon existed in cerebellar mutants lurcher, Purkinje cell degeneration (pcd), and to a lesser extent reeler and wobbler, but was absent in the neurological mutants weaver, jimpy, and motor end plate disease (medH). These observations establish that in several point mutations in mice, central nervous degeneration is associated with dysregulation of IL-1 production by peripheral macrophages.

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.

A comparative immunocytochemical study of human cerebellar cortex in X-chromosome-linked copper malabsorption (Menkes' kinky hair disease) and granule cell type cerebellar degeneration

A comparative immunocytochemical study on the cerebellar cortex with X-chromosome-linked copper malabsorption (X-cLCM) and granule cell type cerebellar degeneration (gc-CD) was carried out by using specific monoclonal antibodies to synaptophysin (SY) and glial fibrillary acidic protein (GFAP). In X-cLCM cases, marked depletion of SY-immunoreactivity (IR) and reduction in number of SY-positive glomeruli were seen in the molecular and granular layers, respectively. Abnormal Purkinje cells occasionally showed moderately strong SY-IR having a fine granular pattern. Proliferation of GFAP-positive cells was observed in the granular and Purkinje cell layers. In the gc-CD case, SY-positive materials were coarsely distributed in a less dense fashion in the molecular layer as compared to a normal control. Purkinje cell perikarya did not show SY-IR. In the gc-CD granular layer, SY-IR appeared to have a coarsely punctate pattern, whereas immunoreactive glomeruli were almost completely absent. A number of GFAP-positive Bergmann cells was observed in the Purkinje cell layer and their fibres were densely and irregularly distributed in the molecular layer, whereas the granular layer was devoid of GFAP-positive cells. We present an immunocytochemical study of the X-cLCM and gc-CD cerebellar cortices, discuss the possible pathogenic mechanisms occurring in these diseases and discuss the usefulness of the SY-immunostaining technique for visualization of axon terminal involvement in these pathological conditions.

The abnormal cerebellar organization of Weaver and reeler mice does not affect the cellular distribution of three neuronal mRNAs

We used in situ hybridization of 35S-labeled antisense RNAs to study the cellular distribution of three neuronal mRNAs. We compared the expression of these RNAs in cerebellar Purkinje neurons in wild-type (C57Bl-6J) mice and in two mutants (Weaver and reeler) known to have abnormal cerebellar morphologies. In normal mice, GAD mRNA is present in four sets of neurons in the cerebellar cortex while calbindin mRNA is present only in Purkinje neurons. Proenkephalin mRNA is present in Golgi II neurons as well as in a set of neurons in the deep part of the molecular layer. Despite the dramatic differences in structural organization and inputs of Purkinje neurons in the cerebella of adult Weaver and reeler mice, the expression of these RNAs appears unchanged. These results support the hypothesis that Purkinje cell cytodifferentiation proceeds autonomously after its inception in early embryonic life.