Development of human cerebellar nuclei. Morphometric study

The morphometric development of the human cerebellar nuclei was examined in 9 fetuses (16-40 weeks of gestation; WG), an infant (2 months old) and 2 adults (16 and 63 years old). With the morphological observation of serial sections of the brain containing the cerebellar nuclei, the authors measured sections to get several morphometric parameters: the volume of nuclear column and number, packing density and cell body area of neurons. Each nucleus (dentate, emboliform, globose and fastigial nucleus) was recognized even at 16 WG. Nerve cells containing Nissl bodies were observed in all nuclei after 23 WG. Degenerative changes were detected in some neurons for every nucleus at 21 and 23 WG. Three stages were observed in the developmental course of nuclear volume and neuronal packing density: the primary or undifferentiated stage at 16 WG, the secondary stage with variability at 21-32 WG and the tertiary stage with monotonous increase (nuclear volume) or gradual decrease (neuronal packing density) after 35 WG. No significant correlation between neuronal number and gestational age was noticed for every nucleus. The analysis of cell body area (neuronal size) demonstrated that the dentate neurons developed after the intermediate or fastigial neurons. It is concluded that there is a critical period between slightly before 20 WG and slightly after 30 WG, matched with the secondary stage in the development of the cerebellar nuclei.     

Math1 is expressed in temporally discrete pools of cerebellar rhombic-lip neural progenitors

We have utilized an in vivo-inducible genetic-fate-mapping strategy to permanently label cohorts of Math1-positive cells and their progeny that arise in the rhombic lip of the cerebellar primordium during embryogenesis. At stages prior to E12.5, with the exception of the deep cerebellar nuclei, we find that Math1 cells migrate out of the cerebellar primordium into the rostral hindbrain to populate specific nuclei that include cholinergic neurons of the mesopontine tegmental system. Moreover, analysis of Math1-null embryos shows that this gene is required for the formation of some of these nuclei. Around E12.5, granule cell precursors begin to be labeled: first, ones that give rise to granule cells that predominantly populate the anterior lobes of the adult cerebellum and later, those that populate progressing more caudally lobes until labeling of all granule cell precursors is complete by E17. Thus, we demonstrate that the cerebellar rhombic lip gives rise to multiple cell types within rhombomere 1.     

Mechanisms of modification of excitatory and inhibitory inputs in various neurons of olivary-cerebellar network

It is known from the experimental data that at different cerebellar neurons there are voltage-dependent Ca2+ channels, NMDA receptors, metabotropic glutamate and GABAB receptors. This receptor arrangement ensures that activation of excitatory and inhibitory input results in changes in activity of protein kinases and phosphatases and subsequent modification of synaptic efficacy. The mechanism of synaptic plasticity is advanced that in accordance with the known experimental data concerning the modification of excitatory and inhibitory inputs to Purkinje cells, granule cells, and deep cerebellar nuclei cells. The mechanism is based on a postulate that phosphorylation/dephosphorylation of AMPA (GABAA) receptors on cerebellar cells causes the LTP/LTD of excitatory (LTD/LTP of inhibitory) transmission. It is assumed that modification rules for Purkinje cells, granule cells, and deep cerebellar nuclei cells, wherein cGMP-dependent protein kinase G is involved in synaptic plasticity, are distinct from those of hippocampal/neocortical cells, wherein cAMP-dependent protein kinase A is involved in synaptic plasticity, since cGMP (cAMP) concentration decreases (increases) with Ca2+ rise.     

Nuclear Localization of the δ Subunit of Ca2+/Calmodulin-Dependent Protein Kinase II in Rat Cerebellar Granule Cells

Abstract : To examine the physiological roles of the δ subunit of Ca²⁺/calmodulin-dependent protein kinase ∥ (CaM kinase ∥δ) in brain, we examined the localization of CaM kinase ∥δ in the rat brain. A specific antibody to CaM kinase ∥δ1-δ4 isoforms was prepared by immunizing rabbits with a synthesized peptide corresponding to the unique carboxyl-terminal end of these isoforms. The prepared antibody did not recognize the α, β, and γ subunits, which were each overexpressed in NG108-15 cells. Immunoblot analysis on various regions and the nuclear fractions from rat brains suggested that some isoforms of CaM kinase ∥δ1-δ4 were abundant in the nucleus in the cerebellum. Total RNA from the cerebellum was analyzed by RT-PCR with a primer pair from variable domain 1 to variable domain 2. We detected the three PCR products δ3.1, δ3.4, and δ3 that contained the nuclear localization signal. These CaM kinase ∥δ3 isoforms were localized in the nuclei in transfected NG108-15 cells. Immunohistochemical study suggested the existence of these isoforms in the nuclei in cerebellar granule cells. These results suggest that CaM kinase ∥δ3 isoforms are involved in nuclear Ca²⁺ signaling in cerebellar granule cells.     

γ-Aminobutyric Acid Agonist-Induced Alterations in the Ultrastructure of Cultured Cerebellar Granule Cells Is Restricted to Early Development

The effect of 4,5,6,7-tetrahydroisoxazolo[5,4-c]-pyridin-3-ol (THIP) on the ultrastructural composition of cultured cerebellar granule cells was investigated during development by quantitative electron microscopy (morphometric analysis). Granule cells were exposed to THIP (150 microM) for 6 h after 7 and 14 days, respectively, in culture. THIP treatment of 7-day-old cultures led to a statistically significant increase in the cytoplasmic density of rough endoplasmic reticulum, Golgi apparatus, vesicles, and coated vesicles, whereas no significant increase in the cytoplasmic density of these organelles was observed in 14-day-old cultures exposed to THIP for 6 h. These findings show that the effect of THIP on the ultrastructural composition of cultured cerebellar granule cells is restricted to early development.     

A Novel Zinc Finger Protein, Zic, Is Involved in Neurogenesis, Especially in the Cell Lineage of Cerebellar Granule Cells

Abstract: To clarify the mechanism of cerebellar development, we have cloned a gene, named zic, encoding a zinc finger protein that is expressed abundantly in granule cells throughout development of the cerebellum. zic has a significant homology to the zinc finger domain of the Caenorhabditis elegans tra1 gene, the Drosophila cubitus interruptus Dominant gene, and the human GLI oncogene. An in situ hybridization study revealed that zic showed a restricted expression pattern in the granule cells and their putative precursor cells. It is also expressed at an early embryonic stage in the dorsal half of the neural tube. The expression pattern and nuclear localization were confirmed by immunohistochemical study. Furthermore, the bacterially expressed zic protein containing the zinc finger domains bound to the GLI -binding sequence. These findings suggest that zic is one of a number of nuclear factors involved in both differentiation in early development and maintenance of properties of the cerebellar granule cells.     

The zebrafish cerebellar rhombic lip is spatially patterned in producing granule cell populations of different functional compartments

The upper rhombic lip, a prominent germinal zone of the cerebellum, was recently demonstrated to generate different neuronal cell types over time from spatial subdomains. We have characterized the differentiation of the upper rhombic lip derived granule cell population in stable GFP-transgenic zebrafish in the context of zebrafish cerebellar morphogenesis. Time-lapse analysis followed by individual granule cell tracing demonstrates that the zebrafish upper rhombic lip is spatially patterned along its mediolateral axis producing different granule cell populations simultaneously. Time-lapse recordings of parallel fiber projections and retrograde labeling reveal that spatial patterning within the rhombic lip corresponds to granule cells of two different functional compartments of the mature cerebellum: the eminentia granularis and the corpus cerebelli. These cerebellar compartments in teleosts correspond to the mammalian vestibulocerebellar and non-vestibulocerebellar system serving balance and locomotion control, respectively. Given the high conservation of cerebellar development in vertebrates, spatial partitioning of the mammalian granule cell population and their corresponding earlier-produced deep nuclei by patterning within the rhombic lip may also delineate distinct functional compartments of the cerebellum. Thus, our findings offer an explanation for how specific functional cerebellar circuitries are laid down by spatio-temporal patterning of cerebellar germinal zones during early brain development.     

Progressive restriction of cell fates in relation to neuroepithelial cell mingling in the mouse cerebellum

Neurogenesis in the cerebellum proceeds through a temporal series of cell production from two separate epithelia, the ventricular zone (VZ) and the external granule cell layer (EGL). Using the laacZ cell lineage tracer in transgenic mice, we describe cellular clones whose dates of birth span the entire period of cerebellar development and deduce a sequence of cell dispersion leading to the final allocation of cells in the cerebellum. Clones probably labeled early during neural tube formation show that individual progenitors can give rise to all cerebellar cell types. The distribution of clonally related granule cells in these clones indicates a mediolateral organization of EGL progenitors already established before the allocation of the EGL progenitors to the cerebellum. Clones restricted to the cerebellar VZ show that the VZ derives progenitors for deep nuclei and multipotent cortical progenitors, which lose their systematic lineage relationship when longitudinal cell intermingling in the cerebellar VZ becomes more limited. The small clones also show that cell dispersion is radial in the internal granule layer and tangential in the molecular layer. Together, the data demonstrate the broad maintenance of the relative order of cells from neural tube stages to the adult cerebellum.     

Interrelated modification of excitatory and inhibitory synapses in three-layer olivary-cerebellar neural network

The model of three-layer olivary-cerebellar neural network with modifiable excitatory and inhibitory connections between diverse elements is suggested. The same Hebbian modification rules are proposed for Purkinje cells, granule (input) cells, and deep cerebellar nuclei (output) cells. The inverse calcium-dependent modification rules for these cells and hippocampal/neocortical neurones or Golgi cells are conceivably the result of the involvement of cGMP and cAMP in postsynaptic processes. The sign of simultaneous modification of excitatory and inhibitory inputs to a cell is opposite and determined by the variations in pre- and/or postsynaptic cell activity. Modification of excitatory transmission between parallel fibers and Purkinje cells, mossy fibers and granule cells, and mossy fibers and deep cerebellar nuclei cells essentially depends on inhibition effected by stellate/basket cells, Golgi cells and Purkinje cells, respectively. The character of interrelated modifications of diverse synapses in all three layers of the network is influenced by olivary cell activity. In the absence (presence) of a signal from inferior olive, the long-term potentiation (depression) in the efficacy of a synapse between input mossy fiber and output cell can be induced. The results of the suggested model are in accordance with known experimental data.     

DNA array analysis of the developing rat cerebellum: transforming growth factor-beta2 inhibits constitutively activated NF-kappaB in granule neurons

The nuclear factor-kappaB (NF-kappaB) pathway is important in neuronal survival and in integration of external signals e.g. cytokines, glutamate, Abeta and nerve growth factor (NGF). During rat cerebellar development NF-kappaB activity is high in granule cells before postnatal day 7 (P7) and declines after P7. Using gene expression profiles, measured by cDNA arrays, up-regulation of transforming growth factor-beta2 (TGF-beta2) was correlated with the developmental down-regulation of NF-kappaB. TGF-beta2 depicted strongest, more than 4-fold, up-regulation in P12 versus P4 cerebella. In situ hybridization and immunohistochemistry confined upregulated TGF-beta2 to granule cells and correlated mRNA and TGF-beta2-protein increase. Finally TGF-beta2 repressed NF-kappaB activity, in an in vitro system resembling migrating cerebellar granule cells. Thus, TGF-beta might fulfill an important role in repressing developmentally activated NF-kappaB in granule neurons.     

Role of Pax6 in development of the cerebellar system.

Post-mitotic neurons generated at the rhombic lip undertake long distance migration to widely dispersed destinations, giving rise to cerebellar granule cells and the precerebellar nuclei. Here we show that Pax6, a key regulator in CNS and eye development, is strongly expressed in rhombic lip and in cells migrating away from it. Development of some structures derived from these cells is severely affected in Pax6-null Small eye (Pax6(Sey)/Pax6(Sey)) embryos. Cell proliferation and initial differentiation seem unaffected, but cell migration and neurite extension are disrupted in mutant embryos. Three of the five precerebellar nuclei fail to form correctly. In the cerebellum the pre-migratory granule cell sub-layer and fissures are absent. Some granule cells are found in ectopic positions in the inferior colliculus which may result from the complete absence of Unc5h3 expression in Pax6(Sey)/Pax6(Sey) granule cells. Our results suggest that Pax6 plays a strong role during hindbrain migration processes and at least part of its activity is mediated through regulation of the netrin receptor Unc5h3.     

Osteocalcin- and Osteopontin-Containing Neurons in the Rat Hind Brain

Immunohistochemistry for osteocalcin (OC) and osteopontin (OPN) was performed to know their distributions in the hind brain of adult rats. OC- and OPN-immunoreactivity (-ir) were detected in neuronal cell bodies, including perikarya and proximal dendrites and the neuropil. In the cranial nerve motor nuclei, numerous OC- and OPN-immunoreactive (-ir) neurons were detected. The neuropil in the cranial motor nuclei mostly showed strong OC- and OPN-staining intensity. The cranial nerve sensory nuclei and other relay and modulating structures in the lower brain stem also contained various numbers of OC- and OPN-ir neurons. The staining intensities in the neuropil were varied among these regions. In the cerebellar cortex, Purkinje cells and granule cells showed OPN-ir but not OC-ir. However, OC- and OPN-ir neurons were abundantly distributed throughout the cerebellar nuclei. The neuropil in the cerebellar nuclei showed moderate OC-ir and strong OPN-ir staining intensities. These findings indicate that the distribution patterns of OC- and OPN-ir neurons were similar in many structures within the hind brain. OC may play a role in modulating neuroprotective function of OPN.     

Activity and calcium regulate nuclear targeting of the calcium channel beta4b subunit in nerve and muscle cells

Auxiliary beta subunits are critical determinants of membrane expression and gating properties of voltage-gated calcium channels. Mutations in the beta4 subunit gene cause ataxia and epilepsy. However, the specific function of beta4 in neurons and its causal relation to neurological diseases are unknown. Here we report the localization of the beta4 subunit in the nuclei of cerebellar granule and Purkinje cells. beta4b was the only beta isoform showing nuclear targeting when expressed in neurons and skeletal myotubes. Its specific nuclear targeting property was mapped to an N-terminal double-arginine motif, which was necessary and sufficient for targeting beta subunits into the nucleus. Spontaneous electrical activity and calcium influx negatively regulated beta4b nuclear localization by a CRM-1-dependent nuclear export mechanism. The activity-dependent shuttling of beta4b into and out of the nucleus indicates a specific role of this beta subunit in neurons, in communicating the activity of calcium channels to the nucleus.     

Alpha-synuclein protects cerebellar granule neurons against 6-hydroxydopamine-induced death

The physiological role of alpha-synuclein, a protein found enriched in intraneuronal deposits characterizing Parkinson's disease, is debated. While its aggregation is usually considered linked to neuropathology, its normal function may be related to fundamental processes of synaptic transmission and plasticity. By using antisense oligonucleotide strategy, we report in this study that alpha-synuclein silencing in cultured cerebellar granule cells results in widespread death of these neurons, thus demonstrating an essential pro-survival role of the protein towards primary neurons. To study alpha-synuclein expression and processing in a Parkinson's disease model of neurotoxicity, we exposed differentiated cultures of cerebellar granule neurons to toxic concentrations of 6-hydroxydopamine (6-OHDA). This resulted in neuronal death accompanied by a decrease of the monomeric form of alpha-synuclein, which was due to both decreased synthesis of the protein and its increased mono-ubiquitination accompanied by nuclear translocation. The essential neuroprotective role of alpha-synuclein was confirmed by the fact that subchronic valproate treatment, which increases alpha-synuclein expression and prevents its nuclear translocation in cerebellar granule cells exposed to 6-OHDA, significantly protected these neurons from 6-OHDA insult. In agreement with the pro-survival role of alpha-synuclein in this model, subtoxic concentrations of alpha-synuclein antisense oligonucleotides, aggravated 6-OHDA toxicity towards granule neurons. Our results demonstrate that normal alpha-synuclein expression is essential for the viability of primary neurons and that its pro-survival role is abolished in 6-OHDA neurotoxic challenge. These results are relevant to more precisely define the role of alpha-synuclein in neuronal cells and to better understand its putative involvement in neurodegeneration.     

Electron microscopical study of synaptic glomeruli in cerebellum transplanted to the anterior eye chamber

Fetal cerebellar anlage from rat fetuses of 15-16 operational days were grafted into the anterior chamber of the eye of adult female albino rat recipients. Survival time of the transplants--containing both cerebellar cortex and cerebellar nuclei--was 2 to 2 1/2 months. Electron microscopical (EM) studies of the thin, under-developed granular layer of the laminated cerebellar cortex revealed the presence of well differentiated cerebellar glomeruli, surrounded by granule cell perikarya. As in the normal cerebellar cortex, the central profile of the glomerular complex was the large mossy terminal, containing spheroid synaptic vesicles, and forming synaptic contacts with dendrites and dendritic digits of the granule cells. Golgi cell axonal varicosities, containing ovoid or pleomorphic synaptic vesicles were found also on the periphery of the glomeruli. In addition, in several synaptic glomeruli, a third neuronal element was also observed, containing flat, discoidal vesicles and receiving synaptic contacts from mossy and Golgi axons, but being also presynaptic to granule cell dendrites. It is suggested that all mossy terminals in the cerebellar transplant originate from the cerebellar nucleus. Morphological evidence is also provided that the presynaptic dendrite-like processes--never found in normal cerebellar cortex--are also processes of nuclear neurons.     

PROPERTIES OF CELL NUCLEI ISOLATED FROM VARIOUS REGIONS OF RAT BRAIN: DIVERGENT CHARACTERISTICS OF CEREBELLAR CELL NUCLEI

Abstract— Cell nuclei were isolated in yields ranging from 38 to 61 per cent from six anatomically defined brain regions of the albino rat. To provide basic information for further studies of altered genomic activity in brain cell nuclei, various properties of these isolated nuclei were measured, including counts of their number, estimates of the distribution of sizes, amounts of RNA, DNA and protein, and endogenous RNA polymerase activity. DNA content per nucleus approximated the accepted value of 6 pg per diploid set of chromosomes. Distributions of nuclear size showed a sensitivity to the concentration of divalent cation, with a shift toward larger nuclear diameters as the Mg concentration was reduced. Cell nuclei from hippocampus, hypothalamus-preoptic region, cerebral cortex, amygdala and midbrain plus brainstem were generally similar in yield, distribution of size, and RNA, DNA and protein content. Cell nuclei from cerebellum differed from those of other brain regions, in all of these parameters. The cerebellum contained a high content of DNA and had an enormous number (8 × 10⁸ per g wet wt.) of cell nuclei of predominantly very small size and characterized by lower ratios of RNA, histones and non-histone protein to DNA and lower endogenous activity of RNA polymerase than nuclei from other brain structures. These properties correlated well with properties of cerebellar tissue, namely, high content of small granule neurons and low ratio of RNA to DNA, and suggest that the small cerebellar nuclei may have relatively inactive genomes. The relationship of 'large' and 'small' cell nuclei to cell types in the brain is discussed.     

A single peripheral injection of basic fibroblast growth factor (bFGF) stimulates granule cell production and increases cerebellar growth in newborn rats

The control of neuronal number is critical for coordinating innervation and target organ requirements. Although basic fibroblast growth factor (bFGF) is known to regulate neuron number in the developing embryonic cortex, its potential role during postnatal brain development remains undefined. To address this issue, the cerebellum, a site of postnatal neurogenesis, was used. Previously, we found that a single peripheral injection of bFGF in newborn rats elicited mitosis of neuronal precursors in the external germinal layer (EGL) 8 h after administration. We now define the sustained effects of bFGF treatment on postnatal granule cell production and cerebellar growth. Seventy-two h after a single injection of bFGF (20 ng/g) in newborn rats, the fraction of BrdU-labeled cells in the EGL increased by 46% without altering apoptotic cell number, consistent with enhanced precursor proliferation. Moreover, bFGF increased mitotically labeled cells by 100% and total cell density by 33% in the internal granular layer (IGL), the final destination of the EGL precursors. Because cerebellar volume also increased by 22%, bFGF-induced proliferation enhanced generation of total IGL neurons and increased cerebellar growth. These morphometric measures were corroborated independently by using DNA quantitation: cerebellar DNA content increased 16% after bFGF injection, consistent with increased neuron number. Furthermore, using DNA quantitation as an index, increased total cerebellar cell number elicited by bFGF injection persisted beyond the neurogenetic period, until P35. We conclude that a single postnatal injection of bFGF increases granule neuron number and enhances cerebellar growth following mitotic stimulation.