Cell Counts of Purkinje and Inferior Olivary Neurons in the 'Hyperspiny Purkinje Cells' Mutant Mouse

The mutant mouse 'hyperspiny Purkinje cells' (hpc) has morphologically abnormal Purkinje cells and below normal intracerebellar calbindin-D28k, a calcium-binding protein that, in the cerebellum, is found only in the Purkinje cells. We counted the Purkinje cells on serial sections stained with thionin or labelled with anti-calbindin-D28k antibodies to investigate whether the depletion of the cerebellar content of calbindin-D28k was correlated with a reduced number of Purkinje cells. We also counted the inferior olivary neurons, as they are one of the major afferents of the Purkinje cells and also contain calbindin-D28k. The hpc mutant mice had 27% fewer cerebellar Purkinje cells and 12% fewer inferior olivary neurons than did controls. Their Purkinje cells were evenly immunostained but slightly atrophic. These data suggest that the depleted cerebellar calbindin-D28k content could be explained both by the loss of some Purkinje cells and the reduced size of the remaining ones.

A comparative study of Purkinje cells in two RORalpha gene mutant mice: staggerer and RORalpha(-/-)

The staggerer (Rora(sg/sg)) mutation is a deletion in the RORalpha gene, one member of a family of nuclear receptor genes related to the retinoic acid receptor. Recently Steinmayr et al. (Proc. Natl. Acad. Sci. USA 95 (1998) 3960) generated a RORalpha null-mutant mouse (Rora(-/-)) by using a targeting vector in which a beta-Gal gene replaces the second finger of the DNA-binding domain of RORalpha. The Rora(-/-) cerebellum is qualitatively a phenocopy of the Rora(sg/sg) one, but the two strains differ slightly in their motor skills. To address the question whether the morphological defects in the Rora(-/-) cerebellum are identical to the Rora(sg/sg) one, we compared number and size of Purkinje cells in both staggerer and RORalpha null-mutant mice, using calbindin (CaBP) immunohistochemistry and revelation of beta-Gal activity. Compared to control cerebella the Rora(sg/sg) cerebellum has 82% fewer CaBP-positive cells. In Rora(-/-) mouse, all the the beta-Gal-positive Purkinje cells also expressed CaBP, but the cerebellum contained 78% less CaBP-positive cells than control, a deficit not different from the one observed in Rora(sg/sg). We show similar mediolateral compartments in Purkinje cell number and cytological abnormality in Rora(sg/sg) and Rora(-/-) mice. These results provide quantitative support for the hypothesis that the cerebellar phenotype in the homozygous Rora(sg/sg) is due to the lack of function of the RORalpha gene.

[Development of the central nervous system in mammals]

In humans, the nervous system is induced during the third gestational week by molecular signals coming from the mesoderm, which modulate the temporal and spatial expression of specific genes in the cells of the dorsal ectoderm. The induced neural plate closes to form the neural tube where the cells actively proliferate in the germinal zone. The neuroblasts which have completed their last division migrate along the fibers of the radial glia to which they adhere, and this movement is essential to establish the normal cerebral organization. The regional identity of the developing brain is governed by the expression of homeobox genes, and the main central structures are clearly delineated by the end of the fifth week. The cerebral cortex begins to form on the seventh week, and the early specification of the cortical areas, which is under genetic control, would be modulated later on by environmental influences. When the neurons have reached their final position, they extend an axon, using surface molecules or diffusible molecules present along its pathway as cues to reach the appropriate target and form a synapse, and this process is a critical step for the establishment of neuronal relationships. The maturation and stabilization of neural networks is characterized by the apoptotic death of roughly 50% of the neurons, due to insufficient neurotrophic support, and by the remodeling of the initial synaptic connections in the surviving neurons. These regressive events occur late in development and depend on both the interactions with the environment and the resulting neuronal activity.

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.

Target-related and intrinsic neuronal death in Lurcher mutant mice are both mediated by caspase-3 activation

The Lurcher (Lc) mutation in the delta2 glutamate receptor gene leads to the presence of a constitutive inward current in the cerebellar Purkinje cells of Lurcher heterozygous mice and to the postnatal degeneration of these neurons. In addition, cerebellar granule cells and olivary neurons of Lc/+ mice die as an indirect effect of the mutation after the loss of their target Purkinje cells. The apoptotic nature of Lc/+ Purkinje cell death remains controversial. To address this question, we studied the involvement of caspase-3, a key effector of apoptosis, in the neurodegenerative processes occurring in Lc/+ cerebellum. Several antibodies recognizing different regions of caspase-3 were used in immunoblotting and immunohistochemical experiments. We demonstrate that pro-caspase-3 is specifically upregulated in the dying Lc/+ Purkinje cells, but not in granule cells and olivary neurons, suggesting that different death-inducing signals trigger variant apoptotic pathways in the CNS. The subcellular localization of pro-caspase-3 was shown to be cytoplasmic and mitochondrial. Active caspase-3 as well as DNA fragmentation was found in numerous granule cells and some Purkinje cells of the Lc/+ cerebellum. Thus, caspase-3 activation is involved in both the direct and indirect neuronal death induced by the Lurcher mutation, strongly supporting the idea that the Lc/+ Purkinje cell dies by apoptosis.

Hemisynaptic distribution patterns of presenilins and beta-APP isoforms in the rodent cerebellum and hippocampus

Healthy brain neurons co-express Alzheimer's disease (AD) related proteins presenilins (PS) and beta-amyloid precursor protein (beta-APP). Deposition of beta-amyloid and PS in the senile plaques of AD brain and their ability to interact in vitro suggest that AD pathology could arise from a defect in the physiological interactions between beta-APP and PS within and/or between neurons. The present study compares the immunocytochemical distribution of PS (1 and 2) and beta-APP major isoforms (695 and 751/770) in the synapses of the cerebellum and hippocampus of the adult rat and mouse. In the cerebellar cortex of both species, the four molecules are immunodetected in the presynaptic or the postsynaptic compartments of synapses, suggesting that they are involved in interneuronal relationships. In contrast, PS and beta-APP are postsynaptic in almost all the immunoreactive synapses of the hippocampus. The different distribution patterns of these proteins in cerebellar and hippocampal synapses may reflect specific physiological differences, responsible for differential vulnerability of neurons to AD synaptic pathology. Defective interactions between beta-APP and PS at the synapses could impede the synaptic functions of beta-APP, inducing the selective loss of synapses that accounts for cognitive impairment in AD.

Role of an enriched environment on the restoration of behavioral deficits in Lurcher mutant mice

Lurcher mutant mice, characterized by massive degeneration of the cerebellar cortex, and normal littermate controls were reared from birth either in standard conditions or in an enriched environment. The effects of this manipulation on motor functions, landmark water maze learning, exploration, and anxiety were evaluated at 3 months of age. Under standard conditions, Lurcher mutants were impaired in comparison to controls on tests of sensorimotor function and had altered exploratory tendencies. The enriched housing improved the motor coordination of Lurcher mutants and decreased the number of trials before reaching criterion in the landmark water maze. In addition to its effects in Lurcher mutants, enriched rearing also increased some behavioral abilities in normal mice. It is hypothesized that enriched housing altered brain morphology or neurochemistry in both normal and cerebellar-damaged animals.

Cerebellar Purkinje cell loss during life span of the heterozygous staggerer mouse (Rora(+)/Rora(sg)) is gender-related

The staggerer mutation causes dysgenesis of the cerebellar cortex in the homozygous mutant (Rora(sg)/Rora(sg)). The mutation acts intrinsically within the Purkinje cells (PCs), leading to cytological abnormalities and a severe deficit in the number of these cells. In contrast, in the heterozygous staggerer (Rora(+)/Rora(sg)), the cytoarchitecture of the cerebellar cortex appears to be normal, but quantitative studies have revealed a significant loss of cerebellar neurons with advancing age. In the heterozygous reeler (+/rl), another mutant presenting a PC loss with age, we have found that only males were affected (Hadj-Sahraoui et al., 1996). In the present study, we have investigated whether a similar gender effect exists in the heterozygous staggerer during life span. PCs were counted on cerebellar sagittal sections in male and female Rora(+)/Rora(sg) and in their Rora(+)/Rora(+) littermates at 1, 3, 9, 13, 18, and 24 months of age. In the Rora(+)/Rora(+), the number of PCs remained stable until 18 months, but there was a 25% significant loss in 24- month-old mice of both genders. During life span, Rora(+)/Rora(+) males had slightly more PC than females. In the Rora(+)/Rora(sg) of both genders, the deficit in PC number was similar at 13 months but it appeared earlier in males, beginning between 1 and 3 months, and was aggravated regularly up to 13 months. By contrast, the decline was delayed and more abrupt in Rora(+)/Rora(sg) females, from a value still normal at 9 months to its maximal extent at 13 months. In view of these results, the heterozygous (Rora(+)/Rora(sg)) mouse offers an interesting model to test the interaction between sex, age, and genetic background on the development and maintenance of cerebellar neuronal populations.

Hu-Bcl-2 transgenic mice with supernumerary neurons exhibit timing impairment in a complex motor task

Programmed neuronal cell death is common during development, and is thought to be important in the elimination of errors in axonal projection, cell position and sculpting of neuronal circuits. However, the potential importance of programmed cell death for complex behaviour in the adult animal has never been addressed. We studied motor abilities in a strain of transgenic mice with neuronal overexpression of the human Bcl-2 protein, which have supernumerary neurons due to reduced developmental cell death. Our results show that these mice have a clear deficiency in fine timing of motor coordination without impairment of basic motor functions. This is the first indication that altered developmental cell death and the consequent neuronal surplus can impair complex behaviour in the adult animal.

Afferent-target cell interactions in the cerebellum: negative effect of granule cells on Purkinje cell development in lurcher mice

Lurcher (Lc) is a gain-of-function mutation in the delta2 glutamate receptor gene that results in a large, constitutive inward current in the cerebellar Purkinje cells of +/Lc mice. +/Lc Purkinje cells fail to differentiate fully and die during postnatal development. In normal mice, interactions with granule cells promote Purkinje cell dendritic differentiation. Partial destruction of the granule cell population in young +/Lc mice by x irradiation resulted in a significant increase in Purkinje cell dendritic growth and improved cytoplasmic structure but did not prevent Purkinje cell death. These results indicate two components to Purkinje cell abnormalities in +/Lc mice: a retardation/blockade of dendritic development that is mediated by interactions with granule cells and the death of the cell. Thus, the normal trophic effects of granule cell interaction on Purkinje cell development are absent in the +/Lc cerebellum, suggesting that granule cells are powerful regulators of Purkinje cell differentiation.

Dopamine turnover in the mediobasal hypothalamus in rat fetuses

In this study, the dopamine turnover in the mediobasal hypothalamus, the key compartment of the neuroendocrine regulation of reproduction, was evaluated in fetal male and female rats. High-performance liquid chromatography with electrochemical detection was used to measure 3,4-dihydroxyphenylalanine, dopamine and 3,4-dihydroxyphenylacetic acid in the mediobasal hypothalamus of fetuses on the 21st day of intrauterine development and in primary cell culture (cell extracts and culture medium) of the same brain region, explanted at the 17th fetal day and maintained for seven days. The same technique was applied to determine dopamine release from fetal neurons of the mediobasal hypothalamus in response to an excess of K+ in the perifusion system or in culture. L-3,4-Dihydroxyphenylalanine, dopamine and 3,4-dihydroxyphenylacetic acid were detected both ex vivo and in culture. The ratios of the concentrations of L-3,4-dihydroxyphenylalanine/dopamine and 3,4-dihydroxyphenylacetic acid/dopamine were significantly higher in vitro than ex vivo, showing a lower rate of dopamine production and a higher rate of its degradation in the experiments in vitro. Moreover, it has been demonstrated that an excess of K+, i.e. a membrane depolarization, resulted in a highly increased release of dopamine in the perifusion system and in culture. The dopaminergic activity in the developing mediobasal hypothalamus showed sexual dimorphism that was manifested in a greater concentration of 3,4-dihydroxyphenylalanine and dopamine, at least in cell extracts of cultures, as well as in a higher rate of dopamine release, both in the perifusion system and in culture in males compared to females. Thus, dopamine is synthesized and released in response to a membrane depolarization in the mediobasal hypothalamus of rats as early as the end of intrauterine development, suggesting its contribution to the inhibitory control of pituitary prolactin secretion.

Severe atherosclerosis and hypoalphalipoproteinemia in the staggerer mouse, a mutant of the nuclear receptor RORalpha

BACKGROUND

Hypoalphalipoproteinemia is the most common lipoprotein abnormality in patients with coronary artery disease, yet its causes are unknown.

METHODS AND RESULTS

We show that the homozygous staggerer (sg/sg) mutant mouse, which carries a deletion within the nuclear receptor RORalpha gene, develops severe atherosclerosis when maintained on an atherogenic diet. In addition, sg/sg mice display a profound hypoalphalipoproteinemia, which is associated with decreased plasma levels of the major HDL proteins, apolipoprotein (apo) A-I and apoA-II. This decrease in HDL levels in sg/sg mice is due to lowered apoA-I gene expression in the intestine but not in the liver. ApoA-II gene expression is unaffected.

CONCLUSIONS

These results suggest that the RORalpha gene contributes to the plasma HDL level and susceptibility to atherosclerosis.

Abnormal IL-1beta cytokine expression in the cerebellum of the ataxic mutant mice staggerer and lurcher

To assess the extent to which interleukin-1beta (IL-1beta) may contribute to the development and/or progression of neurodegenerative processes, we have examined the levels of IL-1beta in the brain of two types of neurological mutant mice, staggerer and Lurcher. Using a quantitative immunological method (enzyme-linked immunosorbent assay, ELISA), we measured IL-1beta in the cerebellum, hippocampus and cerebral cortex of mutant mice at baseline and after peripheral LPS treatment. Two types of IL-1beta expression abnormalities were found in the mutant cerebella: higher basal level in Lurcher and a response to peripheral administration of LPS in staggerer. The association of IL-1beta expression abnormalities with the only brain structure where a massive neurodegeneration occurs supports the role of proinflammatory cytokines in this process.

Role of the cerebellum in exploration behavior

Compared to +/+ mice, Lurcher (+/Lc) mutant mice whose cerebellar cortex is lacking almost all Purkinje cells and granule cells, exhibit a low level of exploration; this deficit is not due to a low level of activity but to both a decreased motivation to explore a novel environment and to spatial deficits. The characteristics of exploration in cerebellectomized +/+ and +/Lc mice suggest that the cerebellum is involved not only in cognitive but also in motivational processes.

Sustained delivery of immunoglobulins from polymer microsources on a narrow surface of the developing rat brain

Studies of postnatal neurogenesis have benefited from the use of a relatively non-invasive method for chronic delivery of bioactive substances to a restricted area of cortex. This method consists of the implantation of an Elvax polymer microsource of active substances close to the targeted brain surface. Receptor ligands, as well as macromolecules such as proteins, peptides and enzymes have been shown to be released by the implants in a sustained manner over weeks. Here we describe the kinetics and immunoreactivity of different immunoglobulins released in vitro and in vivo by Elvax polymer. In vitro, the immunoglobulins first diffuse during a burst phase from the pore network of the polymer matrix. Release continues during a slow phase depending on loading, porosity and volume of the matrix but also on intrinsic properties of immunoglobulins. Elvax microsources loaded either with anti-TAG-1 or with anti-HNK-1 antibodies according to the release data in vitro, are implanted on the posterior cerebellar cortex of postnatal rats during the period when the targeted antigens are expressed by the differentiating cells. After several days, the released immunoreactive antibodies are located at the antigenic sites within the cerebellar cortex close to the implants. The sustained local delivery of immunoglobulins using the Elvax implant method allows access to cell surface and matrix molecules and thereby to the mechanisms they control during postnatal neurogenesis.

Quantitative analysis of cerebellar lobulation in normal and agranular rats

Cerebellar pattern formation was investigated in rats treated with DNA modifying agents. Animals were subjected to combinations of daily injections of methylazoxymethanol acetate (MAM) for the last 6 days gestation and/or localised X-irradiation of the hindbrain on postnatal days 1 and 5 (P1 and P5). Animals were analysed on embryonic day 18 (E18), P0, P3, P7, and P14. Five parameters of the cerebellum were recorded from midsagittal sections: the number of primary lobules; the thickness of the external germinal layer (EGL); the density of cells in the internal granule cell layer (IGL) region; and the midsagittal area and perimeter. In addition, the laterolateral cerebellar distance was calculated. The data demonstrate that pre- and postnatal reduction of the EGL results in reduced cerebellar growth and folding. Cessation of the treatment at birth results in a recovery and eventual overproduction of EGL, but cerebellar growth and the development of fissures lags behind that of normal rats. Pre- and postnatal destruction of the EGL severely limited cerebellar growth and fissuration, and the cerebella contained only five primary lobules at P14. Rats subjected to postnatal X-irradiation alone had a similar low density of granule cells relative to those treated with a combination of prenatal MAM injections and postnatal X-irradiation, and yet the cerebella contained deeper fissures and more lobules (nine at P14). The data indicate that there are two phases of cerebellar folding: the establishment of five lobules that arise independent of granule cell production, and the granule cell-dependent expansion and partitioning of these five principal lobules during postnatal development. We propose that the lack of correlation between the severity of the granule cell loss and degree of lobulation in agranular rats indicates that granule cells exert an inductive influence over lobulation that is in part independent of the forces generated by their production and differentiation.

The cerebellum and postural sensorimotor learning in mice and rats

Animals with cerebellar damage caused by gene mutations, surgical ablations and irradiation by X-rays during developmental stages are impaired in maintaining posture and equilibrium. For most tests, even in animals with total cerebellectomy, postural sensorimotor learning is not abolished. Simpler compensatory movements may be adopted. The acquisition of simple sensorimotor skills occurring after massive damage of the cerebellar cortex may be explained by the modulatory role of the cerebellar deep nuclei during learning processes or by the influence of extracerebellar regions taking over lost cerebellar function.

Neurotrophin-3 promotes cerebellar granule cell exit from the EGL

In the cerebellum, the mRNAs for neurotrophin-3 (NT-3) and its high-affinity tyrosine kinase receptor trkC are expressed by both the differentiated granule cells of the internal granule cell layer (IGL) and their precursors in the external germinal layer (EGL). We have investigated the effects of chronic application of exogenous NT-3 in vivo on cerebellar granule cell genesis and differentiation. NT-3 was applied to the posterior surface of the rat cerebellum from P6 onwards using Elvax implants. At P10 the EGL of cerebellar lobules VII and VIII was significantly reduced in thickness in NT-3 implanted rats when compared with controls. Immunocytochemical analysis of the EGL using antibodies to proliferating cell nuclear antigen (PCNA) revealed that the number of postmitotic, premigratory (PCNA-immunonegative) granule cell precursors was preferentially reduced in the NT-3 implanted rats. In situ DNA fragmentation labelling confirmed that this was not accompanied by increased cell death in the EGL. These results suggest that NT-3 promotes the differentiation of postmitotic, premigratory granule cell precursors, accelerating cell exit from the EGL.

Overexpression of a Hu-bcl-2 transgene in Lurcher mutant mice delays Purkinje cell death

Cerebellar Purkinje cells in the heterozygous Lurcher mutant undergo cell autonomous degeneration beginning in the second week of postnatal development and becoming almost total around 30-45 days. The Lurcher mutation was recently identified as gain-of-function defect in the delta 2 glutamate receptor causing a constitutive current leak, suggesting that +/Lc Purkinje cells die by an excitotoxic mechanism. In previous studies we have shown that overexpression of bcl-2, a key regulator of cell death, in the heterozygous Lurcher mutant does not prevent +/Lc Purkinje cell death. To investigate further the mechanisms of +/Lc Purkinje cell death, we have crossed +/Lc mutants with a second line of Hu-bcl-2 transgenics (NSE73a) that shows an earlier onset of transgene expression and higher expression levels. Analysis of eight +/Lc-NSE73a mutants (4 at 2 months and 4 at 5-6 months) showed that Hu-bcl-2 overexpression delayed, but ultimately could not prevent +/Lc Purkinje cell death.

Immature chemodifferentiation of Purkinje cell synapses revealed by 5'-nucleotidase ecto-enzyme activity in the cerebellum of the reeler mouse

During postnatal development of the rodent cerebellum, a transient enzyme activity of ecto-5'-nucleotidase has been shown in the asymmetrical synapses of Purkinje cells. The alterations of the afferent circuitry and microenvironment of the ectopic Purkinje cells present in the cerebellum of the reeler mutant mouse could enlighten parameters that influence the synaptic 5'-nucleotidase activity of these cells. Ecto-enzyme cytochemistry reveals intense 5'-nucleotidase activity in 43% of synapses of the Purkinje cells throughout the cortex and the core of the reeler cerebellar vermis, although the molecular layer displays large areas with less than 1% of labelled synapses. However, enzymatic labelling is found in considerably more Purkinje cells synapses (73%) throughout the granular layer and the subcortical mass. Climbing fiber synapses of monoinnervated Purkinje cells are labelled by 5'-nucleotidase activity in the molecular layer, as well as asymmetrical synapses made on the subjacent ectopic Purkinje cells by the multiple climbing fibers and by the heterologous afferences. The non-innervated dendritic spines of these cells are also labelled, suggesting that 5'-nucleotidase activity at postsynaptic sites of reeler Purkinje cells does not depend on the presynaptic innervation. Rather, 5'-nucleotidase enzyme activity is enhanced at theses sites when the Purkinje cells have not achieved chemodifferentiation but have conserved immature wiring, i.e., low parallel fiber and multiple climbing fiber inputs.

Differential roles of cerebellar cortex and deep cerebellar nuclei in learning and retention of a spatial task: studies in intact and cerebellectomized lurcher mutant mice

Lurcher mutant mice (+/Lc) exhibit a massive loss of neurons in the cerebellar cortex and the inferior olivary nucleus, while deep cerebellar nuclei are essentially intact. To discriminate the relative participation of the cerebellar cortex and deep structures in learning and memory, 3 to 6-month-old +/Lc mice were subjected to a spatial learning task derived from the Morris water escape. They were able to learn to escape as well as their strain-matched controls (+/+). Seven days later, their scores showed that they had memorized the spatial environment but not as accurately as +/+ mice. Cerebellectomy before training did not significantly alter the escape learning capabilities of either group, whereas cerebellectomy performed after learning completely abolished retention in +/+, as well as in +/Lc, mice. These results suggest that the cerebellum, although not necessary for learning a spatial task, plays a crucial role in its retention, and that the storing structure of spatial information differs in +/+ and +/Lc mice.

staggerer phenotype in retinoid-related orphan receptor alpha-deficient mice

Retinoid-related orphan receptor alpha (RORalpha) is a member of the nuclear receptor superfamily. To study its physiological role we generated null-mutant mice by targeted insertion of a lacZ reporter gene encoding the enzyme beta-galactosidase. In heterozygous RORalpha+/- mice we found beta-galactosidase activity, indicative of RORalpha protein expression, confined to the central nervous system, skin and testis. In the central nervous system, the RORalpha gene is expressed in cerebellar Purkinje cells, the thalamus, the suprachiasmatic nuclei, and retinal ganglion cells. In skin, RORalpha is strongly expressed in the hair follicle, the epidermis, and the sebaceous gland. Finally, the peritubular cells of the testis and the epithelial cells of the epididymis also strongly express RORalpha. Recently, it was reported that the ataxic mouse mutant staggerer (sg/sg) is caused by a deletion in the RORalpha gene. The analysis of the cerebellar and the behavioral phenotype of homozygous RORalpha-/- mice proves identity to sg/sg mice. Although the absence of RORalpha causes dramatic developmental effects in the cerebellum, it has no apparent morphological effect on thalamus, hypothalamus, and retina. Similarly, testis and skin of RORalpha-/- mice display a normal phenotype. However, the pelage hair of both sg/sg and RORalpha-/- is significantly less dense and when shaved shows reluctance to regrow.

Eradication of cerebellar granular cells alters the developmental expression of trk receptors in the rat inferior olive

Granule cells which relay the mossy fibre afferent system to the cerebellar cortex are generated postnatally in mammals. In their absence, the climbing fibres, i.e. the second afferent system to the cerebellum originating in the inferior olivary nucleus, remain in an immature stage, and substantial elimination of redundant synapses they establish on the Purkinje cells does not occur in the rat between day five (P5) and day fifteen (P15). It is generally assumed that synapse elimination is partly regulated by electrical activity which modulates the competition among afferent fibres for the uptake of a limited amount of trophic factors released by the target. The neurotrophins, whose expression is developmentally regulated in the cerebellum, especially in granule cells, could be this retrograde signal. Using RT-PCR, we studied the expression of their trk receptors in the inferior olivary nucleus of developing and adult rats, and its alteration after eradication of the granule cell precursors by X-irradiation on P5. From P0 to P90, the amount of trkA mRNA is low and remains stable in control rats; the high levels of trkB and C mRNAs detected at P0 markedly decrease in parallel from P5 and reach their minimal values at P15, when the process of synapse elimination is completed in the cerebellum. X-irradiation of the cerebellum decreases the level of expression of the three trks, but a transient upregulation of trkC occurs at P10. The down-regulation of trkB and C expression in the inferior olivary nucleus, contemporary with the altered expression of neurotrophins in the cerebellum, suggest that NT-3 and/or BDNF/NT-4/5 could be involved in the remodelling of olivocerebellar relationships during development. In addition, the transient overexpression of trkC after granule cells eradication is consistent with a paracrin effect exerted on the olivary cells by granule cells release of NT-3, at the time when the climbing fibres invest the growing Purkinje cell dendrites in the molecular layer.

Postnatal expression of Hu-bcl-2 gene in Lurcher mutant mice fails to rescue Purkinje cells but protects inferior olivary neurons from target-related cell death

The Lurcher mutant has been extensively studied as a model for cell-autonomous and target-related cell death, yet there are still many unknowns concerning the mechanisms of neuronal degeneration in this mutant. As a key regulator of apoptosis, a bcl-2 transgene has been overexpressed in the heterozygous Lurcher mutant to investigate the effects of BCL-2 on two types of in vivo neuronal cell loss in Lurcher: cell-autonomous Purkinje cell degeneration and target-related olivary neuron death. Six adult +/Lc mutants expressing a human bcl-2 transgene (Hu-bcl-2) were generated by crossing +/Lc mutants with NSE71 Hu-bcl-2 transgenic mice. Analysis of these brains showed that bcl-2 overexpression did not prevent +/Lc Purkinje cell degeneration, but it did rescue most olivary neurons from target-related cell death. Although the number of olivary neurons was equivalent to wild-type numbers, the inferior olive nucleus was significantly shorter in its rostrocaudal extent, suggesting that olivary neurons are atrophied. We propose that Lurcher gene action causes Purkinje cell degeneration independently of a BCL-2-mediated pathway. Furthermore, although bcl-2 overexpression rescues olivary neurons from target-related cell death, it does not prevent the atrophy associated with the loss of target-related trophic support.

Effect of cerebellar granule cell depletion on learning of the equilibrium behaviour: study in postnatally X-irradiated rats

To assess the role of the mossy fibre-granule cell pathway in learning, the cerebellum of young DA/HAN strain rats was irradiated to make the cortex completely or partially agranular. The X-rays were delivered according to two different schedules, between 5-14 postnatal days (early group) and between 10-14 postnatal days (late group). Histological controls at 35 days showed a mean loss of granule cells of 96 +/- 1% in the early group and of 61 +/- 3% in the late group. The irradiated animals were subjected, from day 23 to day 35, to daily sensorimotor training on a rotorod. The scores and the strategy used (walking or hanging) by the rats were noted. The results demonstrate that a partial loss of granule cells due to a late X-irradiation schedule induced mild motor disabilities but no learning deficit, the only problem being difficulty in elaborating rapidly an efficient strategy to solve a novel problem. A sub-total loss of the granule cells, due to an early X-irradiation schedule, induced gross motor disabilities and the animals used hanging > 90% of the time. Due to the discrepancy between the learning abilities, which were preserved at least in part, and the gross motor impairments, the animals elaborated a novel strategy (jumping from the beam), allowing them to escape the experimental situation. This avoidance behaviour may be due to a decrease of anxiety, a lack of behavioural inhibition and/or attentional deficits that have been already observed in several other examples of cerebellar abnormalities.

Enhanced endocrine response to novel environment stress and endotoxin in Lurcher mutant mice

Lurcher mutant mice which are mainly known for their cerebellar degeneration, also display a hyperinducibility of proinflammatory cytokines, such as interleukin-1alpha and beta (IL-1) and tumor necrosis factor alpha (TNF-alpha), in peripheral macrophages. To assess whether this increased responsiveness to inflammatory stimuli is accompanied by a higher pituitary-adrenal response, we compared the adrenocorticotropic hormone (ACTH) and corticosterone response of Lc and wild-type mice to intraperitoneal (i.p.) administration of a cytokine inducer, lipopolysaccharide (LPS). Lurcher mice display resting levels of ACTH and corticosterone similar to those of wild-type mice. LPS (1.25 microg/g) induces a corticosterone surge 2-fold higher in Lurcher than in wild-type mice. By contrast, the response to IL-1alpha (10 ng/g, i.p.) is similar in both genotypes, suggesting that a differential reactivity of the hypothalamo-pituitary adrenal axis to IL-1 does not account for the higher reactivity of Lurcher mice to LPS. To test whether the increased responsiveness of the pituitary-adrenal axis of Lurcher mice generalizes accross stressors, mice were exposed to a novel environment. This condition also induced a surge of ACTH and corticosterone 3.5- and 2-fold higher in Lurcher than in wild-type mice. Prior blockade of IL-1 receptors by injection of IL-1 receptor antagonist (10 microg/g, i.p.) failed to block the response to LPS injection and exposure to novelty. In contrast, immunoneutralization of hypothalamic corticotropin-releasing hormone (CRH) significantly attenuated the ACTH surge and abrogated the difference between Lurcher and wild-type mice in their responses to a novel environment, suggesting that hypothalamic CRH neurons are involved in this excessive response.

Fear decrease in transgenic mice overexpressing bcl-2 in neurons

Neuronal destruction in the amygdala, hypothalamus and cerebellum provokes a diminution in anxiety and neophobia. In transgenic mice that express the human bcl-2 gene under the control of neuron specific enolase promotor (Hu-bcl-2), BCL-2 overexpression reduces the naturally occurring neuronal death, producing an increase of the number of neurons and brain size. Since BCL-2 over-expression has been observed in different parts of the brain and especially in the amygdaloid nuclei, the hypothalamus and the cerebellum, we studied the fear-related behavior of these transgenic mice. Hu-bcl-2 transgenic mice showed a decrease in anxiety and neophobia, indicating that, for this particular behavior, supernumerary neurons elicit the same modification as that observed after neuronal destruction.

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

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

Role of the inferior olivary complex in motor skills and motor learning in the adult rat

The inferior olivary complex of adult rats was chemically destroyed using intraperitoneal injection of 3-acetylpyridine. Animals were submitted to different motor tasks: hanging test, equilibrium test and motor co-ordination test. The different scores show that 3-acetylpyridine-treated rats had motor co-ordination and static equilibrium deficiencies, whereas their rod suspension capabilities were intact. Animals were also trained on an unrotated rod or on a rod rotating at 5, 10 or 20 r.p.m. 3-Acetylpyridine-treated rats were able to maintain their equilibrium on the unrotated rod and at 5 r.p.m. Moreover, after motor training at 5 r.p.m., rats were able to improve their motor skills and reached the same score as controls. Despite their good motor skills, animals were unable to maintain their equilibrium when rotated at 10 and 20 r.p.m. These results suggest that the inferior olivary complex is needed for motor learning involving the temporal organization of movement.

Hypersensitivity of lurcher mutant mice to the depressing effects of lipopolysaccharide and interleukin-1 on behaviour

Lurcher mutant mice are characterized by a fast and almost total loss of olivocerebellar neurones during the first postnatal month, associated with a chronic inflammatory state. To test their brain sensitivity to proinflammatory cytokines, we assessed the behavioural responses of adult male Lurcher and wild type to an i.p. or i.c.v. injection of rat recombinant IL-1 beta, and lipopolysaccharide (LPS). IL-1 beta (15 micrograms kg-1, i.p. or 1 ng i.c.v.) decreased social exploration measured 2, 4 and 6 h later, and this decrease was significantly more pronounced in Lurcher than in wild type mice. LPS (60 micrograms kg-1, i.p. or 5 ng i.c.v.) decreased social exploration measured 2 and 4 h later, and this effect was also significantly more marked in Lurcher than in wild type mice. These results suggest that the chronic inflammatory state which characterizes Lurcher mice renders these animals more sensitive to the effects of cytokines such as IL-1 beta and LPS. This difference may be due to the higher reactivity of brain macrophages and glial cells to LPS and IL-1 in Lurcher mice than in wild type.

Effect of cerebellar granule cell depletion on spatial learning and memory and in an avoidance conditioning task: studies in postnatally X-irradiated rats

Rats of the DA/HAN strain (pigmented rats) were submitted to two experimental tasks consisting in spatial learning (water escape experiment) and in passive avoidance conditioning. These rats were either totally or partially deprived of their granule cells using two different schedules of postnatal X-irradiation of the cerebellum. When they were 3 months old, the animals were submitted to an initial learning session, followed by a retrieval test seven days later. The scores of the rats which were partially deprived of granule cells appeared similar to those of controls, except for a mild deficiency of spatial learning. The learning and retrieval scores of the rats totally deprived of granule cells were similar to those of controls at the passive avoidance conditioning task, but these animals were unable to accurately learn a spatial task and showed memory impairments relative to controls. These results are discussed in terms of cognitive defects.

Delayed spontaneous alternation in intact and cerebellectomized control and lurcher mutant mice: differential role of cerebellar cortex and deep cerebellar nuclei

Lurcher mutant (+/Lc) mice exhibit a massive loss of neurons in the cerebellar cortex and in the inferior olivary nucleus while deep cerebellar nuclei are essentially intact. To discriminate the respective participation of the cerebellar cortex and deep structures in learning and memory, the authors subjected 3- to 6-month-old +/Lc mice to a delayed spontaneous alternation task to test their working and long-term spatial memories. Results show that wild type (+/+) mice alternated above chance even after a 1-hr delay between the forced and choice trials, whereas in +/Lc mice, long-term memory was impaired. Cerebellectomized +/+ mice behave as +/Lc mice (working memory was preserved but long-term memory was not), whereas in the cerebellectomized +/Lc mice, both working and long-term memories were altered. These results are discussed in terms of relationships between the cerebellum and the hippocampus.

Purkinje cell loss in heterozygous staggerer mutant mice during aging

The cerebellum on the heterozygous (+/sg) staggerer mutant mouse has recently been proposed as a model system in which to study the genetic contribution to the normal process of central nervous system aging since there is significant loss of neurons from 3 to 12 months of age (Shojaeian-Zanjani, H., Mariani, J., Delhaye-Bouchaud, N., and Herrup, K. (1992) Dev. Brain Res., 67, 153-160). In the current study we extend our analysis of the changes in Purkinje cell numbers up to 24 months of age in +/sg and C57BL/6J wild-type mice. At 13 and 18 months, while wild-type Purkinje cell numbers remain unchanged, there is a 22-26% loss in the number of Purkinje cells in +/sg after which no further cell loss is observed. Between 18 and 24 months, however, a 22% loss of Purkinje cell occurs in +/+ animals, with the result that by 2 years of age, the size of the Purkinje cell population is again similar in both genotypes. Analysis of the cell loss in both the mediolateral and the anteroposterior dimensions, as well as the immunostaining of Purkinje cells in frontal sections, reveal no obvious regional variation in the Purkinje cell loss. These results suggest that in +/sg, a precocious process of aging affects the size of the Purkinje cell population.

Gender effect on Purkinje cell loss in the cerebellum of the heterozygous reeler mouse

Homozygous mutant mice such as staggerer (sg/sg) or reeler (rl/rl) exhibit a marked ataxia associated with an atrophic cerebellum during the first postnatal weeks and a reduced number of Purkinje cells, the deficit reaching about 75% in sg/sg and 50% in rl/rl as compared to age- and sex-matched mice from the same strain background. These two mutations are classically viewed as recessive, but we have recently shown that heterozygous staggerer (+/sg) mice exhibit a progressive and age-related loss of Purkinje cells between 3 and 12 months of age, despite their apparent clinical normality (Shojaeian-Zanjani et al., 1992). In the present study, we have investigated whether a similar cell loss exists in the cerebellum of heterozygous +/rl mice. The number of Purkinje cells was counted in serial parasagittal sections of the cerebellum of +/rl and their +/+ littermates at 3, 16 and 26 months of age. Our results reveal a 16% deficit in the number of Purkinje cells in 3-month-old +/rl and a 24% one in 16-month-old animals: surprisingly this deficit is only present in the +/rl males, while the females are spared. These results suggest that the reeler gene (D'Arcangelo et al., 1995) exerts its effect on Purkinje cell number in a gender-specific fashion in heterozygous mutant mice.

Increased cerebellar Purkinje cell numbers in mice overexpressing a human bcl-2 transgene

The Purkinje cell is a primary organizer in the development of the cerebellum. Purkinje cells may provide positional information cues that regulate afferent innervation, and Purkinje cell target size controls the adult number of afferent olivary neurons and granule cells. While Purkinje cells are necessary for the survival of olivary neurons and granule cells during periods of programmed cell death, little is known about the survival requirements of Purkinje cells in vivo. To determine if Purkinje cells are subject to programmed cell death during development we have analyzed Purkinje cell numbers in two lines of transgenic mice that overexpress a human gene for bcl-2 (Hu-bcl-2). Bcl-2 is a protooncogene that inhibits apoptosis in many cell types. Overexpression of bcl-2 in vitro and in vivo rescues neurons from trophic factor deprivation or naturally occurring cell death. In the mice analyzed in this study, transgene expression is driven by the neuron-specific enolase promoter that is first expressed embryonically in most regions of the brain in one line and postnatally in the second line. We have counted Purkinje cells in three adult control mice, five early overexpressing transgenics, and three late expressing transgenics. The number of Purkinje cells in the Hu-bcl-2 transgenic mice is significantly increased above control numbers, with an increase of 43% in the embryonically overexpressing line and an increase of 27% in the postnatally overexpressing line. Because bcl-2 overexpression has been shown to rescue other neurons from programmed cell death, the increase in Purkinje cell numbers in overexpressing bcl-2 transgenics suggests that Purkinje cells undergo a period of cell death during normal development.

Over-expression of interleukin-1 beta-converting enzyme mRNA in staggerer cerebellum

Interleukin-1 beta-converting enzyme (ICE), involved in the maturation process of interleukin-1 beta (IL-1 beta, is a homologue of ced-3, a protease required for programmed cell death in Caenorhabditis elegans. Over-expression of ICE induces programmed cell death in certain mammalian cell types, whereas in neurones of the central nervous system such a role has yet to be established. We show that ICE mRNA expression is increased 4-fold in the cerebellum of homozygous staggerer mice, where IL-1 beta mRNA is overexpressed and programmed neuronal cell death occurs. Intraperitoneal injection of endotoxin (LPS) induced a strong phasic increase in IL mRNA levels in the cerebellum, whereas the ICE mRNA level increased only moderately. Involvement of ICE in neuronal cell death in the cerebellum of staggerer mice is suspected.

Cerebellar granule cell differentiation in mutant and X-irradiated rodents revealed by the neural adhesion molecule TAG-1

In the external granular layer of the cerebellum, the granule cell precursors express the transient axonal glycoprotein TAG-1, a molecule involved in adhesion and neurite outgrowth. Granule cells express TAG-1 transiently, just as they extend neurites before migrating over the radial glia. The present study aims to investigate whether the expression pattern of TAG-1 is altered when granule cells develop abnormally. We studied in vivo models in which Purkinje and/or granule cell defects occur during postnatal development. These include the cerebellar mutant mice staggerer and lurcher as well as rats irradiated during postnatal development. Neither alterations in Purkinje cell differentiation nor the related granule cell loss in the mouse mutants impairs the ability of the surviving granule cell precursors to express TAG-1. Also, early granule cell loss in the X-irradiated rats do not disturb the TAG-1 expression phase in the patches of surviving granule cell precursors. Ectopic granule cells found in the adult cerebellum of X-irradiated rats do not bear the molecule, although they are located in the most superficial part of the molecular layer, occupied by the immunopositive cells a few days earlier. Thus, TAG-1 marks a very precise stage of granule cell differentiation, and the inward migration process itself is not required for the cessation of the expression. We postulate that TAG-1 may be involved in local differentiation steps restricted to the deep external granular layer such as parallel migratory routes or synchrony of axonal growth.

Synapse elimination in the central nervous system: functional significance and cellular mechanisms

Recent research into the developmental elimination of supernumerary synapses has increased understanding of this process. In this review we discuss synapse elimination both at the neuromuscular junction and in the central nervous system, considering some possible underlying mechanisms suggested by recent studies. In addition a well-described example of central nervous system synapse elimination, the climbing fiber-Purkinje cell synapse of the cerebellum, is used to explore the functional significance of synaptic regression during brain development.

Motor behavior of heterozygous staggerer mutant (+/sg) versus normal (+/+) mice during aging

Three- to 24-month-old heterozygous staggerer (+/sg) and control (+/+) C57B16 mice were subjected to a motor test on a rota rod rotating at 30 or 40 revolutions per minute. The scores were evaluated by the time during which they maintained their equilibrium without falling down. Although the scores of both +/sg and +/+ animals decreased with age, the scores of +/sg mice were constantly lower at 3, 6 and 12 months and this difference was already significant at 3 months, i.e., before the 30% loss of Purkinje cells, granule cells and inferior olivary neurons which occurs between 3 months and 1 year in the mutant. At 18 months and beyond, scores no longer differed in both groups. These results show that there is no strict correlation between neuronal death in the cerebellar cortex and motor behavior on the rota rod. However, the difficulties in maintaining their equilibrium on the rota rod observed in +/sg mice as young as 3 months, indicate a deficit in accurate motor control which could be due to subtle structural or neurochemical disorders that probably precede neuronal death. Therefore, in the heterozygous staggerer, behavioral motor disturbance is a sign of cerebellar dysfunction which appears earlier than alterations in neuronal number.

5'-nucleotidase activity as a synaptic marker of parasagittal compartmentation in the mouse cerebellum

In the molecular layer of the mouse cerebellum, the histochemical activity of the adenosine-producing ectoenzyme 5'-nucleotidase discloses a parasagittal pattern of alternating enzyme-rich and enzyme-poor bands. In the rat, 5'-nucleotidase activity transiently labels cerebellar synapses during postnatal development and shifts later on towards an exclusive glial location in the molecular layer. We therefore asked whether different ultrastructural expression of 5'-nucleotidase would account for the light microscopic pattern seen in the adult mouse cerebellum. Using an enzyme cytochemical method, we localized 5'-nucleotidase activity on the glial cells and at the main types of asymmetrical synapses in the developing and mature cerebellum of the mouse. The percentage of labelled synapses increased until adulthood within the 5'-nucleotidase-positive bands. Here, the vast majority (86%) of the synapses were labelled against only 27% within the negative bands in the adult. Thus, 5'-nucleotidase appears as a marker of glia and of Purkinje cell synapses across cerebellar compartments. Changes in purinergic neuromodulation and/or cell adhesion mediated by 5'-nucleotidase across bands might participate in the functional differentiation of the cerebellar parasagittal subsets.

Abnormal ipsilateral functional vibrissae projection onto Purkinje cells multiply innervated by climbing fibers in the rat

We have previously shown that synapse elimination occurring in the climbing fiber (CF)-Purkinje cell (PC) relationships during normal postnatal development is likely involved in the refinement of vibrissae projections onto the cerebellar cortex. In normal adult rats, CF-mediated vibrissae projections onto cerebellar Purkinje cells of the vermis of lobule VII are strictly contralateral and located in a narrow microzone whereas they are widely distributed in rats whose PCs remained multiply innervated by CFs due to postnatal irradiation. Given the proximity of this microzone to the midline, the question arose as to whether this synapse elimination process could participate in the segregation of ipsilateral and contralateral projections. In the present study, we compared the topographical map of the ipsilateral and contralateral CF-mediated projections of the third row of vibrissae onto the vermal PCs of lobule VII in adult normal rats and in polyinnervated rats. Using intracellular electrophysiological recordings, we examined the responsiveness of PCs to mechanical stimulation of vibrissae, and positioned responsive cells on an averaged planar map of lobule VII. In normal rats no ipsilateral responses were found, while in irradiated rats ipsilateral responses were distributed evenly from the midline to 700 microns apart. These results suggest that synapse elimination participates in the segregation of ipsi and contralateral mystacial inputs to the vermis.

Differential roles of cerebellar cortex and deep cerebellar nuclei in the learning of the equilibrium behavior: studies in intact and cerebellectomized lurcher mutant mice

Three- to 6-month-old lurcher mutant mice (+/lc), which exhibit a massive loss of neurons in the cerebellar cortex and in the inferior olivary nucleus but whose deep cerebellar nuclei are essentially intact, were trained daily, for 9 days, to maintain their equilibrium upon a rota rod rotating at 20 or 30 revolutions per minute (rpm). Their scores were measured and their behavior upon the rotating rod quantified in comparison to those of matched control (+/+) mice. Lurcher mice were able to learn to maintain their equilibrium efficiently when rotated at 20 rpm but were not when rotated at 30 rpm. After cerebellectomy, the equilibrium capabilities of the animals were much altered, especially in +/lc. These results show that the deep cerebellar nuclei are sufficient for motor learning, provided the task is not too difficult (20 rpm), but that the cerebellar cortex is required when the task is more difficult (30 rpm). Therefore, it can be concluded that the adaptive motor capabilities of lurcher mice are less developed than those of control animals.

Inflammatory processes induce beta-amyloid precursor protein changes in mouse brain

In Alzheimer disease, a combination of genetic predisposition and environmental factors may contribute to changes in beta-amyloid precursor protein (APP) expression, beta-amyloid peptide deposition, and neuronal loss. Factors such as head injury or acute infection that trigger inflammatory processes may play a crucial role in development of the disease. In the present in vivo study, we showed that, in mouse brain, peripheral stimulation with lipopolysaccharide (LPS) induced a transient increase in the inflammatory cytokine mRNAs (interleukin 1 beta and interleukin 6), followed by changes in expression of APP isoforms in the cerebellum but not in the cerebral cortex. These changes consisted of a decrease in the APP-695 and an increase in the Kunitz protease inhibitor-bearing isoforms (KPI-APP). In the cerebellum of the staggerer mouse mutant, where a severe loss of Purkinje and granule cells occurs, basal mRNA levels of these interleukins were elevated and an increase in the KPI-APP/APP-695 ratio compared to wild-type mice was observed. These abnormalities were further accentuated by LPS stimulation. This study shows that acute and chronic inflammatory processes play an important role in changes in APP expression possibly associated with neurodegeneration.

Quantitative analysis of the Purkinje cell and the granule cell populations in the cerebellum of nude mice

In the nude mutant, a well-known model of athymia in mouse, abnormalities have been reported in the cerebellum, including a 45% reduction in cerebellar size and neuronal loss (Henderson et al., 1981). The present work was aimed at reappraising the claimed anomalies by using quantitative cytological techniques. We counted the Purkinje and the granule cells, on serial sagittal sections stained with thionin, in the cerebella of nude mice (nu/nu) compared with their Balb/c controls (+/+). The latero-lateral extent of the cerebellar cortex was statistically different (mean +/- standard deviation) between the nude (7.05 +/- 0.45 mm, n = 3) and the control mice (8.05 +/- 0.35 mm, n = 3) (Student's t-test, p < 0.05). The number of Purkinje cells was not statistically different (p = 0.98) between the nude mice (159,880 +/- 5,225, n = 3) and the control ones (160,060 +/- 12,300, n = 3). The number of granule cells (x 10(6)) did not differ significantly (p = 0.40) in nude mice (m = 12.1 +/- 1.8, n = 3) from the controls (m = 13.2 +/- 0.8, n = 3). Immunohistochemistry with a specific marker of Purkinje cells, calbindin protein, did not reveal any qualitative difference between the nude and the control Purkinje cells. The only slight but significant difference concerned the mean cross-sectional area of the Purkinje cell somas: 188.2 microns 2 (n = 149) in the control animals and 176.3 microns 2 (n = 150) in the nude mice, (p < 0.01). In conclusion, our data indicate only a mild effect, if any, of the nude mutation upon the cerebellar neuronal population.

Developmental studies of the inferior olivary nucleus in staggerer mutant mice

The neurological mutation, staggerer, causes a severe disruption in the integrity of the olivo-cerebellar circuitry. The primary site of action is the Purkinje cell population which is reduced in cell number, with cells that are atrophic in dendritic structure, small in size and ectopic in position. This primary defect has a cascade effect on the Purkinje cell-afferent populations, leading to the target-related cell death of virtually all of the cerebellar granule cells and the majority of the neurons in the inferior olive. As part of our ongoing study of the cell-cell interactions in the cerebellar circuitry, we have studied the inferior olive of the staggerer mutant from birth to adulthood. We find that the reduction in olive neuron number does not occur until after birth in the mutants. On the day of birth, the number of cells is indistinguishable in mutants and in wild type. Similarly, we find that the four principal subnuclei of the olive are well defined at birth, but regress to a state of poor resolution during the first 3 postnatal weeks. Finally, Golgi impregnations reveal that of the two morphological classes of inferior olive neurons, only one class--the Type II or complex dendritic type survive in the mutant. These results are discussed in terms of their implications for the cell--cell interactions in the developing olivocerebellar circuit.

Contribution of peripheral macrophages and microglia to the cellular reaction after mechanical or neurotoxin-induced lesions of the rat brain

Lesions of the central nervous system result in invasion of peripheral phagocytes and/or in situ activation and proliferation of microglia, depending on the direct or indirect nature of the injury. Neurotoxins which are widely used to induce neurodegeneration have been reported to elicit a pure microglial reaction when administered intraventricularly. However, the mechanical lesion at the injection site, although remote from the lesioned area, could give access to blood-derived cells. Therefore, this study compares the phagocytic reaction occurring after a traumatic lesion of the brain causing a breakdown of the blood-brain barrier (BBB), or after degeneration of the inferior olivary neurons induced by intraperitoneal administration of 3-acetylpyridine, a process that respects the integrity of the BBB as suggested by the results of intravascular injection of Evans blue. The identification of the macrophages at the lesion site used specific binding of the B4 isolectin from Griffonia simplicifolia, preloading of the peripheral monocytes/macrophages with trypan blue, and characteristic morphological features. In traumatically lesioned rats, the lectin-labeled macrophages were mainly large rounded peripheral cells recruited 1-3 days postlesion, whereas in chemically lesioned rats, the cellular reaction appeared 24-36 h postinjection and peaked between 3 and 12 days before undergoing a slow decline. Lectin binding and morphological characteristics indicated that these small cells were reactive microglia. These results confirm that a brain injury leaving the BBB intact involves essentially the recruitment and/or the proliferation of microglia.

Enlargement of olivo-cerebellar microzones in the agranular cerebellum of adult rats

Previous work on normal adult rat showed that the vibrissae project, through the climbing fiber (CF) system, onto the Purkinje cells (PCs) of the contralateral cerebellar hemivermis of lobule VII. The highly elaborated CF projections from a given row of vibrissae delimit a narrow parasagittal zone which can be regarded as a functional olivo-cerebellar microzone. Interestingly, the adult one-to-one relationship between PCs and CFs is preceded by a transient phase during which each PC receives synaptic inputs from several CF collaterals which will be eliminated but one, when granule cells begin to establish synapses on PCs. Therefore, the question arose as to whether this synaptic elimination process could participate in the refinement of the topographical organization of CF projections and could contribute to the formation of such precise peripheral maps onto the cerebellum. In the present study, the topographical map of the CF-mediated projection of mystacial vibrissae onto the vermal PCs of lobule VII was determined in adult rats whose cerebellar PCs remain polyinnervated by olivary CFs due to degranulation by postnatal X-irradiation. Using intracellular recordings, we examined the responsiveness of PCs in lobule VII during mechanical stimulation of the 3rd row of contralateral vibrissae, and positioned cells responding to the stimulation on an averaged planar map of lobule VII. Comparison of the results to those obtained in our previous work on normal rats showed that the activated cells were more numerous and more diffusely distributed.(ABSTRACT TRUNCATED AT 250 WORDS)

IL-1 and LPS induce a sexually dimorphic response of the hypothalamo-pituitary-adrenal axis in several mouse strains

Sexual steroids are involved in the regulation of the immune system and modulate directly the synthesis of interleukin-1 (IL-1) by macrophages. Bacterial lipopolysaccharides (LPS) and IL-1 stimulate the hypothalamo-pituitary-adrenal (HPA) axis. As a result, glucocorticoids initiate a negative feedback loop since they inhibit the synthesis of IL-1. In this study we wanted to estimate the respective effects of genetic background, gender and sex-hormones (as assessed by gonadectomy) upon the HPA axis response to either IL-1 or LPS of mice of both sexes in 3 different strains: B6, CBA and B6 x CBA. Plasma ACTH and corticosterone, the predominant glucocorticoid in rodent, were determined by radioimmunoassay. IL-1 alpha or beta, 10 ng (per g. body weight), were injected i.p. and mice bled 2 h later. In the 3 strains, Il-1 alpha induced ACTH and IL-1 alpha and beta induced corticosterone responses, nearly 2-fold higher in females than in males. In the 3 strains, ovariectomy, as compared to sham operation, lowered the corticosterone values, while orchidectomy had no effect. LPS, 1.25 micrograms (per g. body weight), was injected i.p. and mice bled 2, 4 or 6 h later. The kinetics of the corticosterone response was sex- and strain-dependent. After 4 h, females of each strain had higher levels than males. Gonadectomy, as compared to sham operation, lowered the response of both males and females in the B6 strain, but was unefficient in the CBA one.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of the target in synapse elimination: studies in cerebellum of developing lurcher mutants and adult chimeric mice

As the mature nervous system is sculpted out of its embryonic anlage, regressive events are a surprisingly common feature. As one example, the establishment of adult innervation in the CNS and PNS often involves a massive withdrawal of previously formed functional synapses. In the cerebellum, the one-to-one relationship of inferior olivary climbing fibers to Purkinje cells is preceded by a transient stage in which each Purkinje cell is multiply innervated. The regulation of this regressive event is still not fully understood; previous studies suggested that some stimulus from the maturing granule cells is necessary. We have used the lurcher (Lc) mutation as a model system in which to study this phenomenon. In lurcher mice, Purkinje cells degenerate during the first few postnatal weeks, after receiving synaptic contacts from both inferior olivary neurons and granule cells. We have recorded the climbing fiber responses both in lurcher mutants at postnatal days 14-20 (P14-P20) and in adult lurcher chimeras. In the latter, experimental genetics are used to create a situation in which untreated wild-type Purkinje cells are present in an environment that ranges from 100% wild-type to nearly mutant. We found that in P14-P16 lurcher mutants, most of the cells recorded (75%) remained polyinnervated, whereas in wild-type control mice, only 10% of the Purkinje cells retained their multiple innervation. By P18-20, it was difficult to find Purkinje cells in the lurcher mutants that would withstand an intracellular electrode. Nonetheless, in those cells that were successfully impaled, most remained multiply innervated. By this age in wild-type mice, 100% of the Purkinje cells are monoinnervated.(ABSTRACT TRUNCATED AT 250 WORDS)