Studies of the dendritic tree of wild-type cerebellar Purkinje cells in lurcher chimeric mice

Determining factors for optimal neuronal and glial Golgi-Cox staining

Golgi staining allows for the analysis of neuronal arborisations and connections and is considered a powerful tool in basic and clinical neuroscience. The fundamental rules for improving neuronal staining using the Golgi-Cox method are not fully understood; both intrinsic and extrinsic factors may control the staining process. Therefore, various conditions were tested to improve the Golgi-Cox protocol for vibratome-cut rat brain sections. Optimal staining of cortical neurons was achieved after 72 h of impregnation. Well-stained neurons in both cortical and subcortical structures were observed after 96 h of impregnation. The dendritic arborisation pattern of cortical neurons derived from the 72-h impregnation group was comparable to those of the 96 and 168-h impregnation groups. The entire brain was stained well when the pH of the Golgi-Cox solution was 6.5 and that of the sodium carbonate solution was 11.2. Lack of brain perfusion or perfusion with 0.9% NaCl did not influence optimal neuronal staining. Perfusion with 37% formaldehyde, followed by impregnation, only resulted in glial staining, but perfusion with 4% formaldehyde facilitated both glial and neuronal staining. Whole brains required longer impregnation times for better staining. Although every factor had a role in determining optimal neuronal staining, impregnation time and the pH of staining solutions were key factors among them. This modified Golgi-Cox protocol provides a simple and economical procedure to stain both neurons and glia separately.

Deletion of the GluRδ2 Receptor in the Hotfoot Mouse Mutant Causes Granule Cell Loss, Delayed Purkinje Cell Death, and Reductions in Purkinje Cell Dendritic Tree Area

Recent studies have found that in the cerebellum, the δ2 glutamate receptor (GluRδ2) plays a key role in regulating the differentiation of parallel fiber-Purkinje synapses and mediating key physiological functions in the granule cell-Purkinje cell circuit. In the hotfoot mutant or GluRδ2 knockout mice, the absence of GluRδ2 expression results in impaired motor-related tasks, ataxia, and disruption of long-term depression at parallel fiber-Purkinje cell synapses. The goal of this study was to determine the long-term consequences of deletion of GluRδ2 expression in the hotfoot mutant (GluRδ2 ^ho/ho ) on Purkinje and granule cell survival and Purkinje cell dendritic differentiation. Quantitative estimates of Purkinje and granule cell numbers in 3-, 12-, and 20-month-old hotfoot mutants and wild-type controls showed that Purkinje cell numbers are within control values at 3 and 12 months in the hotfoot mutant but reduced by 20 % at 20 months compared with controls. In contrast, the number of granule cells is significantly reduced from 3 months onwards in GluRδ2 ^ho/ho mutant mice compared to wild-type controls. Although the overall structure of Purkinje cell dendrites does not appear to be altered, there is a significant 27 % reduction in the cross-sectional area of Purkinje cell dendritic trees in the 20-month-old GluRδ2 ^ho/ho mutants. The interpretation of the results is that the GluRδ2 receptor plays an important role in the long-term organization of the granule-Purkinje cell circuit through its involvement in the regulation of parallel fiber-Purkinje cell synaptogenesis and in the normal functioning of this critical cerebellar circuit.

Smaller Absolute Quantities but Greater Relative Densities of Microvessels Are Associated with Cerebellar Degeneration in Lurcher Mice

Degenerative affections of nerve tissues are often accompanied by changes of vascularization. In this regard, not much is known about hereditary cerebellar degeneration. In this study, we compared the vascularity of the individual cerebellar components and the mesencephalon of 3-month-old wild type mice (n = 5) and Lurcher mutant mice, which represent a model of hereditary olivocerebellar degeneration (n = 5). Paraformaldehyde-fixed brains were processed into 18-μm thick serial sections with random orientation. Microvessels were visualized using polyclonal rabbit anti-laminin antibodies. Then, the stacks comprised of three 5-μm thick optical sections were recorded using systematic uniform random sampling. Stereological assessment was conducted based on photo-documentation. We found that each of the cerebellar components has its own features of vascularity. The greatest number and length of vessels were found in the granular layer; the number of vessels was lower in the molecular layer, and the lowest number of vessels was observed in the cerebellar nuclei corresponding with their low volume. Nevertheless, the nuclei had the greatest density of blood vessels. The reduction of cerebellum volume in the Lurcher mice was accompanied by a reduction in vascularization in the individual cerebellar components, mainly in the cortex. Moreover, despite the lower density of microvessels in the Lurcher mice compared with the wild type mice, the relative density of microvessels in the cerebellar cortex and nuclei was greater in Lurcher mice. The complete primary morphometric data, in the form of continuous variables, is included as a supplement. Mapping of the cerebellar and midbrain microvessels has explanatory potential for studies using mouse models of neurodegeneration.

Sprouty genes prevent excessive FGF signalling in multiple cell types throughout development of the cerebellum

Fibroblast growth factors (FGFs) and regulators of the FGF signalling pathway are expressed in several cell types within the cerebellum throughout its development. Although much is known about the function of this pathway during the establishment of the cerebellar territory during early embryogenesis, the role of this pathway during later developmental stages is still poorly understood. Here, we investigated the function of sprouty genes (Spry1, Spry2 and Spry4), which encode feedback antagonists of FGF signalling, during cerebellar development in the mouse. Simultaneous deletion of more than one of these genes resulted in a number of defects, including mediolateral expansion of the cerebellar vermis, reduced thickness of the granule cell layer and abnormal foliation. Analysis of cerebellar development revealed that the anterior cerebellar neuroepithelium in the early embryonic cerebellum was expanded and that granule cell proliferation during late embryogenesis and early postnatal development was reduced. We show that the granule cell proliferation deficit correlated with reduced sonic hedgehog (SHH) expression and signalling. A reduction in Fgfr1 dosage during development rescued these defects, confirming that the abnormalities are due to excess FGF signalling. Our data indicate that sprouty acts both cell autonomously in granule cell precursors and non-cell autonomously to regulate granule cell number. Taken together, our data demonstrate that FGF signalling levels have to be tightly controlled throughout cerebellar development in order to maintain the normal development of multiple cell types.

The Lurcher mouse: Fresh insights from an old mutant

The Lurcher mouse was first discovered in 1954 as a spontaneously occurring autosomal dominant mutation that caused the degeneration of virtually all cerebellar Purkinje cells and most olivary neurons and granule cells. More recent molecular studies revealed that Lurcher is a gain of function mutation in the delta2 glutamate receptor (GluRdelta2) that converts an alanine to threonine in the highly conserved third hydrophobic segment of GluRdelta2. The mutation converts the receptor into a constitutively leaky cation channel. The GluRdelta2 receptor is predominantly expressed in cerebellar Purkinje cells and in the heterozygous Lurcher mutant (+/Lc). Purkinje cells die due to the mutation in the GluRdelta2 receptor, while olivary neurons and granule cells degenerate due to the loss of their Purkinje cell targets. The purpose of the review is to provide highlights from 5 decades of research on the Lurcher mutant that have provided insights into the developmental mechanisms that regulate cell number during development, cerebellar pattern formation, cerebellar physiology, and the role of the cerebellum in CNS function.

Don't get too excited: mechanisms of glutamate-mediated Purkinje cell death

Purkinje cells (PCs) present a unique cellular profile in both the cerebellum and the brain. Because they represent the only output cell of the cerebellar cortex, they play a vital role in the normal function of the cerebellum. Interestingly, PCs are highly susceptible to a variety of pathological conditions that may involve glutamate-mediated 'excitotoxicity', a term coined to describe an excessive release of glutamate, and a subsequent over-activation of excitatory amino acid (NMDA, AMPA, and kainite) receptors. Mature PCs, however, lack functional NMDA receptors, the means by which Ca(2+) enters the cell in classic hippocampal and cortical models of excitotoxicity. In PCs, glutamate predominantly mediates its effects, first via a rapid influx of Ca(2+)through voltage-gated calcium channels, caused by the depolarization of the membrane after AMPA receptor activation (and through Ca(2+)-permeable AMPA receptors themselves), and second, via a delayed release of Ca(2+) from intracellular stores. Although physiological levels of intracellular free Ca(2+) initiate vital second messenger signaling pathways in PCs, excessive Ca(2+) influx can detrimentally alter dendritic spine morphology via interactions with the neuronal cytoskeleton, and thus can perturb normal synaptic function. PCs possess various calcium-binding proteins, such as calbindin-D28K and parvalbumin, and glutamate transporters, in order to prevent glutamate from exerting deleterious effects. Bergmann glia are gaining recognition as key players in the clearance of extracellular glutamate; these cells are also high in S-100beta, a protein with both neurodegenerative and neuroprotective abilities. In this review, we discuss PC-specific mechanisms of glutamate-mediated excitotoxic cell death, the relationship between Ca(2+) and cytoskeleton, and the implications of glutamate, and S-100beta for pathological conditions, such as traumatic brain injury.

Progressive atrophy of cerebellar Purkinje cell dendrites during aging of the heterozygous staggerer mouse (Rora(+/sg))

Staggerer (Rora(sg/sg)) is an autosomal mutation in an orphan nuclear hormone receptor gene, RORalpha, that acts intrinsically within the Purkinje cells and causes dysgenesis of the cerebellar cortex. Purkinje cell number is severely reduced, and the surviving cells are small with poorly developed dendrites. In contrast, the cytoarchitecture of the cerebellar cortex of the heterozygous staggerer (Rora(+/sg)) appears to be normal. However, quantitative studies have revealed a premature loss of Purkinje cells with advancing age. Most of the loss (25--30%) is complete by 13 months with little change thereafter. To address the question of whether all Purkinje cells, even the surviving ones, are affected by aging even though their cell bodies remain intact, we studied the evolution with age of the dendritic arbor through a semi-quantitative analysis of Golgi-impregnated Purkinje cells. A total of ten different morphological parameters were measured in 4-, 12- and 22-month-old wild type and heterozygous Rora(+/sg) mice. While the effects of the aging process are apparent in the wild type cerebellum, they are considerably accelerated in the Rora(+/sg) mouse. By 12 months the Rora(+/sg) Purkinje cell dendrite is as atrophic as a wild type dendrite from a 22-month-old and the dendritic regression continues well beyond the period of cell death in the heterozygous Rora(+/sg) mouse.

Abnormalities in the cerebellum and brainstem in homozygous lurcher mice

The lurcher mutation induces Purkinje cell degeneration in heterozygous mice, and neonatal death in homozygous animals. Using the D6Mit16 Simple Sequence Length Polymorphic marker in F2 hybrids between AKR +/+ mice and B6+/Lc mice, homozygous lurcher fetuses and newborns as well as heterozygous and normal littermates were identified, and their brain morphology was analysed. In homozygous lurcher embryos at embryonic day 18 and neonates the cerebellum was hypotrophic, particularly in the posterior half. Purkinje cells were smaller in the whole cerebellum and showed a maturational delay. Calretinin-positive cells were less frequently observed in the depth of the vermis than in normal mice. Both Purkinje cells and the vermal calretinin-positive cells were more abnormal in fetuses at day 19 and newborn mutants than one day earlier. An abnormal number of pycnotic cells were observed in the cerebellum, especially in newborn mutants. Brainstem abnormalities were characterized by abnormal curvature, caudal displacement of the pontine gray nuclei which were located caudally along the ventral border of the superior olivary complex, a drastic decrease in Purkinje cell axons in all the vestibular nuclei and the presence of dystrophic processes in at least two calbindin-positive cell groups of the dorsal pontine region. These results show that the mutation, which is semidominant in Purkinje cells, is recessive in other cell groups of the cerebellum and brainstem. They reveal that the sequence leading to Purkinje cell death appears to be similar in homozygous and heterozygous mice, although occurring earlier and worsening more quickly in the former. Lastly, they confirm the absence of effect of the mutation on the neurons of the inferior olivary complex.

Conditional ablation of cerebellar astrocytes in postnatal transgenic mice

Astrocytes have been proposed to have multiple roles in the development and maintenance of the vertebrate CNS. To facilitate documentation of these roles, we designed a transgene to enable their ablation at selectable times. The transgene consists of the coding region for the herpes simplex virus-thymidine kinase (HSV-TK) under the control of the human glial fibrillary acidic protein gene promoter. The HSV-TK is innocuous but converts the antiherpetic agent ganciclovir (GCV) to a toxic product that interferes with DNA replication in proliferating cells. In a developmental study, transgenic mice were treated with GCV during the first postnatal week, with evaluation at P19. Treated mice displayed severe ataxia. Histological examination revealed disrupted astrocyte development, particularly in the cerebellum, with marked secondary effects on other cell types. Cerebellar defects included a loss in the numbers of astrocytes and an overall reduction in cerebellar size and disruption of the normally well defined cellular layers. Radial glia were disordered, Purkinje cells were ectopically distributed and displayed abnormal dendritic trees, and granule cells were markedly depleted. These effects were more severe in animals treated on postnatal day 1 versus treatment at day 5. A major factor causing granule cell death was excitotoxicity attributable to activation of NMDA receptors. These results suggest a critical role for astrocytes in cerebellar development.

The numerical matching of source and target populations in the CNS: the inferior olive to Purkinje cell projection

During a defined critical period of development, if the target of a neuronal population is removed, there is a massive decrease in the number of neurons that survive into adulthood. Previous studies have found that source neuron number is a strictly linear function of target size. The current work extends these observations to the inferior olive-->Purkinje cell projection. Three distinct model systems have been used: (i) lurcher<-->wild-type aggregation chimeras, (ii) staggerer<-->wild-type chimeras and (iii) naturally occurring polymorphisms in Purkinje cell number found in different inbred mouse strains. Total neuron numbers were counted in the inferior olive and plotted as a function of the number of Purkinje cells in the contralateral cerebellar cortex. In lurcher mutants and chimeras, the relationship between these values is well described by a straight line. This suggests that, like the granule-->Purkinje cell circuit, the olive-->Purkinje cell circuit uses a linear algorithm to achieve a numerical balance. The results from the two other model systems were not as clear cut. In the staggerer chimeras, we found only a rough correlation between neuron and target numbers and in the inbred strains there was no discernible relationship at all. These findings indicate that in the final analysis, there are multiple factors involved in the determination of the number of olive cells surviving into adulthood. The potential contribution of sustaining collaterals and afferent inputs is discussed as well as the possible existence of different subcircuits of olivocerebellar connections, each with its own numerical matching function.

Abnormal Purkinje cell dendrites in lurcher chimeric mice result from a deafferentation-induced atrophy

Previous studies of Purkinje cell dendrites in lurcher<-->wild-type mouse chimeras (lurcher chimeras) have documented the surprising occurrence of unusual atrophic dendritic morphologies among the wild-type cells of the mosaic cerebella. We have hypothesized that these aberrant morphologies arise from a process of developmental deafferentation that is due to the unique loss of mutant Purkinje cells in these chimeras. These earlier studies left unanswered the question of whether the abnormal dendrites were the result of a blocked developmental process (agenesis) or regressive events that deform a previously well-developed dendritic arbor (atrophy). Using a set of simple morphometric measures, we now examine wild-type Purkinje cells in young lurcher chimeras. At postnatal day 20, normal Purkinje cell development is nearly but not fully complete. In lurcher chimeras, the morphologies of the wild-type Purkinje cell dendrites are similar to those in wild-type controls of the same age. This means that they are larger in height, width, and cross-section than their counterparts in adult lurcher chimeras. The younger cells exhibit almost none of the atrophic morphologies described in mature animals. We conclude that the aberrant morphologies found in adult lurcher chimeras arise from atrophy rather than through a failure in development. Furthermore, consideration of the details of the wild-type dendrites in the lurcher chimeras leads to the proposal that the height and width of the Purkinje cell dendritic tree are controlled by two independent mechanisms.

Stunted morphologies of cerebellar Purkinje cells in lurcher and staggerer mice are cell-intrinsic effects of the mutant genes

Purkinje cells in the neurological mutants lurcher and staggerer exhibit a number of abnormal properties; mutant<==>wild-type chimeras have shown that these properties are direct effects of the mutant gene. What has remained unexplored are the numerous dendritic abnormalities that the two mutant Purkinje cells exhibit. In staggerer, Purkinje cells have rudimentary, unbranched dendrites that lack tertiary branchlet spines. In lurcher, before the Purkinje cells die, their dendrites remain short and underdeveloped. To determine whether or not a system of healthy afferents (or other environmental factors) would alter either of these phenotypes, we examined young lurcher and adult staggerer mouse chimeras using Golgi impregnation. In postnatal day 20 (P20) lurcher chimeras, we found two distinct morphological classes of Purkinje cells. One, inferred to be wild type, had a dendritic structure similar to normal Purkinje cells in age-matched controls. The other consisted of cells with small somata, reduced dendritic arbors, and multiple dendritic processes, making them indistinguishable from Purkinje cells in P20 lurcher mutants. We also examined mature staggerer chimeras. We found no evidence that the stunted morphology of staggerer Purkinje cells is rescued in mosaic animals but observed numerous examples of medium to large neurons resembling atrophic Purkinje cells of staggerer mutants. These results suggest that the dendritic abnormalities described in both mutants reflect cell autonomous, developmental genetic blocks in the cytological maturation of the cerebellar Purkinje cell. The implication is that the action of the wild-type alleles at these two loci are required to execute a normal program of dendritic development.

Purkinje cell dendritic arbors in chick embryos following chronic treatment with an N-methyl-D-aspartate receptor antagonist

The normal development of Purkinje cell dendrites is dependent on afferent innervation. To investigate the role of neuronal activity in Purkinje cell dendritic development, chick embryos were chronically treated with a potent, selective, and systemically active competitive N-methyl-D-aspartate (NMDA) receptor antagonist, NPC 12626. The NMDA receptor was chosen as a target for pharmacological blockade because of the importance of the NMDA receptor in synaptic plasticity and stabilization in development. Chick embryos were given daily injections of NPC 12626 (25 to 100 mg/kg) from embryonic day 14 (E14) to E17. The initial injections of NPC 12626 dramatically blocked embryo movements, but activity levels partially recovered following subsequent injections. Embryo movements were reduced by 24% at the end of the experiment. Embryos were killed on E18, and their brains processed for Golgi-Cox staining. The morphology of Golgi-stained Purkinje cells in drug-treated embryos was similar to control embryos. Morphometric analysis showed, however, that chronic treatment with NPC 12626 resulted in a 19% reduction in Purkinje cell dendritic tree area and a 13% reduction in the number of dendritic branch points. The overall width and height of the drug-treated dendritic trees were not significantly different from controls, suggesting that NPC 12626 reduced Purkinje cell dendritic area by interfering with branch formation. The volume of the granule cell layer and the heights of the molecular and external granule cell layers was not reduced, suggesting that NPC 12626 treatment did not simply delay development. These results suggest that activation of the NMDA receptor may mediate the afferent-target interactions in the cerebellum that regulate the elaboration of Purkinje cell dendrites.

Effects of nervous mutation on Purkinje cell compartments defined by Zebrin II and 9-O-acetylated gangliosides expression

The cerebellum is organized into a series of parasagittally aligned bands which are well delineated in the adult mouse by the largely complementary immunostaining of Purkinje cell groups with the monoclonal antibodies Zebrin II (ZII; antigen: aldolase C) and P-path (antigen: 9-O-acetyl gangliosides). We examined the effect of nervous mutation on compartmental organization using these markers and an antibody to calbindin. In nervous mutant, up to 90% of Purkinje cells die in late postnatal development. The size of the cerebellum is about half that of normal, and caudal lobules appear to decrease in size more than anterior ones. Surviving Purkinje cells corresponded to P-path positive ones that were concentrated in two bilateral bands in the vermis and in medial portions of the hemispheres. Only small numbers of ZII positive cells remained, confirming the report by Wassef et al. with Zebrin I antibody. They were primarily located in caudal lobules IX, X and a portion of lobule IV, paraflocculus and flocculus, and their immunoreactivity was weak compared to that of normal. ZII positive cells are dominant in these caudal lobules, while P-path positive cells dominate in rostral lobules in normal mice, and the similar tendency remains in mutant. Thus, the nervous gene action respects not only sagittal compartments delineated by two antibodies, but also rostro-caudal gradient. The cause of the dominant survival of P-path positive cells awaits future study.

Partial reconstruction of the adult Lurcher cerebellar circuitry by neural grafting

Solid cerebellar grafts, taken from normal mouse embryos (gestational day 12-14), were transplanted into the cerebellum of adult Lurcher mice. The degree of Purkinje cell replacement was analysed one to three months after transplantation by means of immunocytochemistry (antibodies against calbindin, cGMP-dependent protein kinase and neurofilament proteins) and electron microscopy. Grafted Purkinje cells succeed in moving out of the graft and migrate into the host cerebellar cortex. They are present next to the graft in the granule cell and molecular layers, and far from the graft remnant, only in the molecular layer, indicating that, although both layers subserve Purkinje cell migration, the molecular layer is the ultimate target. In the host molecular layer, axons of transplanted Purkinje cells form thick bundles running in the frontal plane over long distances. Most of them terminate in the upper granule cell layer by enlarged bulbs resembling collapsed growth cones. Axons reaching their normal targets (the neurons of the deep cerebellar nuclei) are observed only in cases where the granule cell layer is disrupted and/or grafted Purkinje cells remain in the white matter. The projection is massive only from grafts lying in the close vicinity of the target neurons. Electron-microscopic analysis of grafted Purkinje cells populating the host cerebellar cortex reveals that their synaptic investment is abnormal. In the molecular layer, where the normal inputs are reduced, the compartmentation in proximal and distal dendritic segments is severely affected, climbing fibre synapses only form on a minority of grafted cells and "pinceau" formations are absent. In the granule cell layer, the synaptic investment is similar to that of Purkinje cells in agranular cerebellum, and even heterelogous synapses with mossy fibres have been observed. These results, compared to those previously obtained with grafting experiments in Purkinje cell degeneration mutant mouse, allow us to conclude that: (i) the Purkinje cell-deficient molecular layer of the host, despite its severe atrophy and reactive gliosis, still exerts a positive neurotropism specific for grafted Purkinje cells; (ii) the unlesioned host granule cell layer underlying the molecular layer containing grafted Purkinje cells, even if almost depleted of granule cells, remains an obstacle for the re-establishment of a corticonuclear projection; and (iii) the degree of synaptic integration of grafted Purkinje cells is directly related to the nearby presence of available host axon terminals. Hence, owing to the atrophy of the Lurcher cerebellum, the postgrafting restoration of the cerebellar cortical circuit is much less complete in this mutant.

Purkinje cell dendrites in staggerer<-->wild type mouse chimeras lack the aberrant morphologies found in lurcher<-->wild type chimeras

In lurcher<-->wild type mouse chimeras (lurcher chimeras), mutant Purkinje cells are transiently present and probably provide target support for afferent granule cells during the sensitive period of target-dependent cell death. Previous studies demonstrate that wild type Purkinje cells in the cerebella of mature lurcher chimeras often have atrophic dendritic morphologies, leading to the hypothesis that developmental deafferentation of wild type Purkinje cells occurs uniquely in lurcher chimeras following the period of mutant Purkinje cell loss. Other studies document the survival of a disproportionately large number of granule cells in these animals. Based on cell birthdate analyses, the hypothesis further proposes that deafferentation induces an up-regulation of trophic activity among the Purkinje cell population and the consequent rescue of late generated granule cells that might otherwise be lost to target related cell death. In the present study, we take advantage of phenotypic differences between the staggerer and lurcher mutations to test this hypothesis. While staggerer<-->wild type chimeras (staggerer chimeras) resemble lurcher chimeras in several respects, including extensive cell loss, they differ in that staggerer Purkinje cells never provide target support for granule cells. Hence the hypothesis predicts that Purkinje cells in these animals should not exhibit the atrophic morphologies found in lurcher chimeras. We have developed a new semiquantitative method for scoring dendritic morphology in a large number of Golgi-impregnated cells. We have used this method to characterize the distribution of wild type Purkinje cell morphologies in staggerer chimeras, and to compare these with the corresponding distributions of morphologies in lurcher chimeras and wild type<-->wild type chimeras. We find that morphologies in staggerer chimeras closely resemble those in control chimeras. Furthermore, Purkinje cells in both staggerer and wild type chimeras differ significantly from those in lurcher chimeras. These results confirm a direct prediction of the hypothesis.

Early development of the Lurcher cerebellum: Purkinje cell alterations and impairment of synaptogenesis

The postnatal development of the heterozygous Lurcher (Lc/+) mouse cerebellum is characterized by Purkinje cell death with a concomitant reduction in granule cell number. In order to evaluate possible relationships between these two events, this study investigates early morphological abnormalities of the Purkinje cells and possible defects in the formation of their synaptic investment. Cerebella of Lurcher and control age-matched (from P8 to P16) mice were analysed by calbindin immunostaining, silver impregnation and quantitative electron microscopy. Direct signs of Purkinje cell anomaly are obvious from P8, four days before the onset of the necrotic process. These signs include the presence of axonal swellings and perinuclear clumps of chromatin, and a general delayed process of maturation, evidenced in cell bodies (incomplete development of the basal polysomal mass) and in dendritic trees (hyperspinous dendrites, delayed formation of proximal and distal compartments). Also from P8, the external granular layer is reduced in thickness. Despite these abnormalities, the onset of the synaptogenesis between Purkinje cells and their specific inputs (parallel fibres, climbing fibres and basket cell axons) takes place on schedule and, at P8, no defect has been noticed. On and after P10, the rate of parallel fibre synaptogenesis is decreased. Very few climbing fibres translocate from their perisomatic to their peridendritic locations, and basket cell axons fail to develop 'pinceau' formations. All these results suggest that before the death of the Purkinje cell by P12, there is an impaired maturation of these neurons provoked by the Lurcher gene action. The hypoplasia of the external granular layer and the altered synaptic investment of the Purkinje cell after P10 are considered to be consequences of the early Purkinje cell defect.

Cerebellar Purkinje cells provide target support over a limited spatial range: evidence from lurcher chimeric mice

The distribution of Purkinje cells, granule cells, and olivary neurons was quantitatively analyzed in a lurcher +/Lc in equilibrium C3H/HeJ chimera in which the surviving wild type Purkinje cells were unilaterally distributed in the left hemicerebella. The left hemisphere of this mouse contains 7600 Purkinje cells, approximately 10% of the number of Purkinje cells in inbred C3H/HeJ mice. The right hemisphere contains 300 Purkinje cells, all of which are found within 200 microns of the midline. As in other +/Lc in equilibrium wild type chimeras, the ratio of granule cells to Purkinje cells is increased in the left hemisphere, reflecting increased granule cell survival. In the right hemisphere, however, the number of granule cells is reduced to that found in +/Lc mutants. In the inferior olive, almost twice as many neurons are found in the right nucleus as opposed to the left nucleus. As the projections of olivary neurons are crossed, the number of olivary neurons is increased in the nuclei that project to the cerebellar hemisphere containing Purkinje cells compared to the olivary nuclei that project to the cerebellar hemisphere with almost no Purkinje cells. The preferential survival of granule cells and olivary neurons that either occupy or project to the hemicerebellum containing Purkinje cells suggests that the availability of trophic support from target Purkinje cell neurons is spatially restricted.

The fine structure of the Purkinje cell and its afferents in lurcher chimeric mice

Lurcher is an autosomal dominant mutation in the mouse. Heterozygote (+/Lc) animals lose 100% of their cerebellar Purkinje cells during the first postnatal month. Aggregation chimeras made between +/Lc and wild-type embryos have been used to demonstrate that this neuronal cell death is a cell autonomous property of the +/Lc Purkinje cells. In lurcher chimeras, all +/Lc PCs die while wild-type Purkinje cells survive in the numbers expected. Although they are normal in number, previous work from our laboratories has shown that when the genetically wild-type Purkinje cells are present in the mosaic environment of the lurcher chimeric mouse they develop a very unusual morphology. Their dendritic trees are small, and the caliber of their dendrites is increased. This paper examines the fine structure of these unusual cells as well as their afferent fibers. Purkinje cell somas in the lurcher chimera have an increased number of lysosomes and the rough endoplasmic reticulum is improperly configured. In the majority of the Purkinje cell dendrites the organelles are disorganized; it is not certain whether this is a cause or a consequence of the increase in dendritic caliber previously reported. Presynaptic fibers have been examined and, while all classes of expected synapses can be observed, the numbers of synaptic profiles visible in any one thin section are reduced. Climbing fiber terminations on the Purkinje cells were smaller than normal with a greatly diminished number of constituent vesicles. Unexpectedly, we found unusual morphologies among the Bergmann glial fibers and the presence of unusual (or ectopic) astrocytic like glial cells near the pial surface. These changes in turn were accompanied by an increase in the number of glial-like fibers near the pia in some parts of the chimeric cerebellar cortex. The results are discussed in light of our knowledge of other mutant mice, and a hypothesis is put forward to explain some of our results.