Neuronal nuclear antigen (NeuN): a marker of neuronal maturation in early human fetal nervous system

Chromosome 1p and 19q deletions in malignant glioneuronal tumors with oligodendroglioma-like component

Malignant glioneuronal tumors (MGNT) are suggested to be a new entity of glioma defined morphologically as any malignant glioma showing immunohistoichemical evidence of neuronal differentiation. We encountered seven cases of MGNT with oligodendroglioma-like component and investigated alternations of chromosome 1p and 19q in these tumors. Seven patients ranged from 33 to 62 years of age, four females and three males. Immunohistochemical study of these tumors was performed using neuronal markers (synaptophysin, neurofilament, beta-tubulin, chromogranin A and NeuN), astrocytic marker (GFAP) and Ki-67. We undertook a molecular cytogenetic study of tumor specimens obtained from seven patients using fluorescence in situ hybridization (FISH) with DNA probes mapping to chromosome 1p36, 1q25, 19p13 and 19q13. Histologically, these tumors resembled anaplastic oligodendroglioma. Immunohistochemically, tumor cells were immunoreactive for synaptophysin (7/7), neurofilament (6/7), beta-tubulin (5/7), chromogranin A (4/7), NeuN (2/7) and GFAP (7/7). The Ki-67 labeling index ranged from 4.5% to 20.7%. FISH analysis demonstrated either 1p or 19q deletion in all seven cases (100%) and both 1p and 19q deletions in five cases (71%). The 1p deletion was detected in six of seven cases (86%) and 19q deletion was also detected in six (86%). 1p and 19q deletions were present in MGNT, especially those with oligodendroglial components. We suggest that the oligodendroglial-like feature was associated with not only 1p or 19q loss but also differentiation along neuronal cell lines as a factor of favorable prognosis in glial tumors. It is inappropriate to make a diagnosis of oligodendroglioma based only on morphological resemblance to oligodendroglia.

Microenvironment drives the endothelial or neural fate of differentiating embryonic stem cells coexpressing neuropilin-1 and Flk-1

The observation that the architecture of the cardiovascular and nervous systems is drawn by common guidance cues and the closeness between neural progenitors and endothelial cells in the vascular niche strongly suggests the existence of links between endothelial and neural cell fates. We identified an embryonic stem cell-derived discrete, nonclonal cell population expressing the two vascular endothelial growth factor receptors neuropilin-1 (Nrp1) and Flk1 that differentiates in vitro toward endothelial or neural phenotypes depending on microenvironmental cues. When microinjected in the chick embryo, Nrp1(+) cells integrate within the host, developing vessels and brain, and acquire endothelial and neural markers, respectively. These results show that precursors of endothelial cells and precursors of neural cells arise from the same pool of differentiating embryonic stem cells and share the expression of Nrp1 and Flk1. These data reinforce the parallelism between vascular and nervous system at the level of cell fate and commitment and open new perspective in regenerative medicine of neurovascular diseases.

Neurogenesis in the chronic lesions of multiple sclerosis

Subcortical white matter in the adult human brain contains a population of interneurons that helps regulate cerebral blood flow. We investigated the fate of these neurons following subcortical white matter demyelination. Immunohistochemistry was used to examine neurons in normal-appearing subcortical white matter and seven acute and 59 chronic demyelinated lesions in brains from nine patients with multiple sclerosis and four controls. Seven acute and 44 of 59 chronic multiple sclerosis lesions had marked neuronal loss. Compared to surrounding normal-appearing white matter, the remaining 15 chronic multiple sclerosis lesions contained a 72% increase in mature interneuron density, increased synaptic densities and cells with phenotypic characteristics of immature neurons. Lesion areas with increased neuron densities contained a morphologically distinct population of activated microglia. Subventricular zones contiguous with demyelinated lesions also contained an increase in cells with phenotypes of neuronal precursors. These results support neurogenesis in a subpopulation of demyelinated subcortical white matter lesions in multiple sclerosis brains.

Analysis of calcium ion homeostasis and mitochondrial function in cerebellar granule cells of adult CaV 2.1 calcium ion channel mutant mice

CaV 2.1 voltage-gated calcium channels (VGCC) are highly expressed by cerebellar neurons, and their dysfunction is linked to human disorders including familial hemiplegic migraine, episodic ataxia type 2 and spinocerebellar ataxia type 6. Altered calcium homeostasis, due to dysfunctional Ca(V 2.1 VGCC can severely affect mitochondrial function, eventually leading to neuronal cell death. We study leaner and tottering mice, which carry autosomal recessive mutations in the gene coding for the alpha 1A pore-forming subunit of CaV 2.1 VGCC. Both leaner and tottering mice exhibit cerebellar ataxia and epilepsy. Excessive leaner cerebellar granule cell (CGC) death starts soon after postnatal day 10, but it is not known whether the degree of CGC cell death observed in adult leaner mice is significantly different from wild type mice. We used Fluoro-Jade and TUNEL staining to quantify apoptotic cell death in leaner and wild type CGC. We investigated calcium homeostasis, mitochondrial function and generation of reactive oxygen species (ROS) in isolated CGC, using indicator dyes Fura-2AM, TMRM and CMH2DCFDA, respectively. We observed a small but significant increase in number of apoptotic adult leaner CGC. Calcium homeostasis and mitochondrial function also were altered in leaner CGC. However, no significant differences in ROS levels were observed. It is possible that CGC death in leaner mice may be related to mitochondrial dysfunction but may not be directly related to decreased basal intracellular calcium.

Cell-specific alterations of glutamate receptor expression in tuberous sclerosis complex cortical tubers

OBJECTIVE

Genetic loss of TSC1/TSC2 function in tuberous sclerosis complex (TSC) results in overactivation of the mammalian target of rapamycin complex 1 pathway, leading to cellular dysplasia. We hypothesized that the dysplastic cells in TSC tubers are heterogeneous, including separable classes on a neuronal-glial spectrum, and that these dysplastic cells express glutamate receptor (GluR) patterns consistent with increased cortical network excitability.

METHODS

Surgically resected human cortical tubers and nondysplastic epileptic cortical samples were analyzed by double-label immunocytochemistry for coexpression of neuronal and glial markers, the TSC1/TSC2 pathway downstream molecule phospho-S6 (pS6) and GluR subunits, and compared with control cortical tissue. Western blotting was used to quantify changes in GluR subunit expression in tubers versus controls.

RESULTS

We demonstrate that cortical tubers contain a broad spectrum of cell types including disoriented pyramidal cells, dysplastic neurons, giant neuroglial cells, dysplastic astroglia, and reactive astrocytes. Dysplastic neurons, giant cells, and dysplastic astroglia express high levels of pS6 and demonstrate altered GluR subunit composition, resembling those of normal immature neurons and glia. In contrast, nondysplastic neurons in TSC and non-TSC epileptic lesions express lower pS6 levels and display changes in GluR subunit expression that are distinct from the patterns seen in tuber dysplastic cells.

INTERPRETATION

This work significantly expands the spectrum of abnormal cells recognized in tubers beyond the classic tuber giant cell and demonstrates cell-specific abnormalities in GluR expression that may contribute to seizure pathogenesis in TSC. Furthermore, these results suggest that subunit-specific antagonists may be of potential use in the treatment of epilepsy in TSC.

The Differential Diagnosis of Central Nervous System Tumors: A Critical Examination of Some Recent Immunohistochemical Applications

Context.—As we write, novel antibodies that may well alter the routine practice of surgical neuropathology are in development, characterization, and the early stages of clinical use. These will be used for purposes of tumor subclassification, as prognostic markers, as identifiers of potential therapeutic targets, and as predictors of treatment response.

Objective.—To provide for nonspecialists a critical assessment of the peer-reviewed literature (necessarily colored by our own experience) as it pertains to several immunohistochemical reagents that have been recently forwarded as adjuncts to the histologic typing of central nervous system tumors.

Data Sources.—We address in these pages only antibodies that are commercially available, that have been the subjects of multiple published series, and that we have had occasion to use in the course of everyday problem solving.

Conclusions.—Discussion concentrates on the use of 4 antibodies: BAF47 in the diagnosis of atypical teratoid/ rhabdoid tumor, OCT4 in intracranial germinoma, β-catenin in craniopharyngioma, and NeuN as a marker of neuronal differentiation in neuroepithelial neoplasms.

Immunohistochemical markers for quantitative studies of neurons and glia in human neocortex

Reproducible visualization of neurons and glia in human brain is essential for quantitative studies of the cellular changes in neurological disease. However, immunohistochemistry in human brain specimens is often compromised because of prolonged fixation. To select cell lineage-specific antibodies for quantitative studies of neurons and the major types of glia, we used 29 different antibodies, different epitope retrieval methods, and different detection systems to stain tissue arrays of formalin-fixed human brain. The screening pointed at CD45/leukocyte common antigen (LCA), CD68(KP1), 2',3' cyclic nucleotide phosphatase (CNPase), glial fibrillary acidic protein (GFAP), HLA-DR, Ki67, neuronal nuclei (NeuN), p25alpha-antigen, and S100beta as candidates for future cell counting purposes, because these markers visualized specific neuronal and glial cell bodies. However, significant negative correlation between staining result and formalin fixation was observed by blinded scoring of staining for CD45/LCA, CNPase, GFAP, and NeuN in brain specimens fixed by immersion and stored up to 10 years in 4% formalin solution at room temperature, independent of donor sex and postmortem interval. In contrast, improved preservation of NeuN and CNPase staining, and full preservation of GFAP and CD45/LCA staining in tissue fixed by perfusion and stored for up to 3 years in 0.1% paraformaldehyde solution at 4C, indicated that immunohistochemistry can be performed in well-preserved biobank material.

Unbiased cell quantification reveals a continued increase in the number of neocortical neurones during early post-natal development in mice

The post-natal growth spurt of the mammalian neocortex has been attributed to maturation of dendritic arborizations, growth and myelination of axons, and addition of glia. It is unclear whether this growth may also involve recruitment of additional neurones. Using stereological methods, we analysed the number of neurones and glia in the neocortex during post-natal development in two separate strains of mice. Cell counting by the optical fractionator revealed that the number of neurones increased 80-100% from the time of birth to post-natal day (P)16, followed by a reduction by approximately 25% in the young adult mouse at P50-55. Unexpectedly, at the time of birth less than half of the neurones and at P8 only 65% of the neurones expressed neuronal nuclear antigen (NeuN), a marker of mature post-migratory neurones. In accordance with these observations, NeuN acquisition by neurones in layer VIa was delayed until P16. The number of glia reached its maximum at P16, whereas the number of oligodendroglia, identified using a transgenic marker, increased until P55, the latest time of observation. Neurones continued to accumulate in the developing neocortex during the first 2 weeks of post-natal development, underscoring fundamental differences in brain development in the mouse compared with human and non-human primates. Further, delayed acquisition of NeuN by neurones in the deepest neocortical layers and continued addition of oligodendroglia to the neocortex suggested that neocortical maturation should be regarded as an ongoing process continuing into the young adult mouse.

Expression of neuronal markers in the secondary neurulation of chick embryos

OBJECTIVE

The goal of our study was to evaluate the expression patterns of neuronal antigens during the process of secondary neurulation.

MATERIALS AND METHODS

Chick embryos of Hamburger and Hamilton stages 16, 18, 20, 22, 24, 26, 30, 35, 40, and 45 were harvested, and tail sections were processed for neuronal antigen studies.

RESULTS AND CONCLUSIONS

The areas and periods showing positive reactions for each antigen are as follows: neuronal cell adhesion molecule (N-CAM): the secondary neural tube and notochord from stages 18 to 26 and the germinal and mantle layers from stages 30 to 45; synaptophysin: the caudal cell mass, secondary neural tube, and notochord from stages 22 to 26, the germinal and mantle layers from stages 30 to 45, and the marginal layer at the later stages of development; neurofilament-associated protein (3A10): the dorsal white matter, dorsal root ganglion, and scattered cells around the germinal layer from stages 35 to 45; and neuronal nuclear-specific protein (NeuN): the mantle layer at stage 35, which shows decreased reaction at stages 40 and 45; islet-1: no remarkable staining on the caudal cell mass or on the other neural structures at all stages. Our results indicate that neuronal markers of the secondary neurulation in chick embryos have their own chronological patterns of expression. At early stages of secondary neurulation, N-CAM and synaptophysin are thought to modulate the differentiation of structures derived from the caudal cell mass. At later stages, N-CAM, synaptophysin, 3A10, and NeuN seem to be involved in the maturation of the caudal spinal cord.

Neurogenesis impairment and increased cell death reduce total neuron number in the hippocampal region of fetuses with Down syndrome

We previously obtained evidence for reduced cell proliferation in the dentate gyrus (DG) of fetuses with Down syndrome (DS), suggesting that the hippocampal hypoplasia seen in adulthood may be caused by defective early neuron production. The goal of this study was to establish whether DS fetuses (17-21 weeks of gestation) exhibit reduction in total cell number in the DG, hippocampus and parahippocampal gyrus (PHG). Volumes of the cellular layers and cell number were estimated with Cavalieri's principle and the optical fractionator method, respectively. We found that in DS fetuses all investigated structures had a reduced volume and cell number. Analysis of cell phenotype showed that DS fetuses had a higher percentage of cells with astrocytic phenotype but a smaller percentage of cells with neuronal phenotype. Immunohistochemistry for Ki-67, a marker of cycling cells, showed that DS fetuses had less proliferating cells in the germinal zones of the hippocampus and PHG. We additionally found that in the hippocampal region of DS fetuses there was a higher incidence of apoptotic cell death. Results show reduced neuron number in the DS hippocampal region and suggest that this defect is caused by disruption of neurogenesis and apoptosis, two fundamental processes underlying brain building.

MATH-1 production by an adult medulloblastoma suggestive of a cerebellar external granule cell precursor origin

Radiological, histological and molecular findings in an uncommon adult case of cerebellar medulloblastoma suggested an external granular cell precursor origin. This 19-year-old woman had a 1-month history of progressively worsening headache. Neuroimaging studies demonstrated a homogeneously enhanced well-circumscribed mass lesion in the right cerebellar hemisphere and she underwent surgery. Postoperative neuronal imaging studies showed that the tumor located in the cerebellar folia had been removed totally. Pathological examination identified it as a desmoplastic medulloblastoma with subpial and subarachnoid infiltration and some infiltration into the molecular and granular layer via the perivascular space. Polymerase chain reaction and immunohistochemical findings revealed the presence of MATH-1, expressed in cerebellar external granule cell precursors during fetal development, in the tumor cells. These findings suggest that the tumor arose from external granule cell precursors of the cerebellum and that it was therefore of neuronal lineage.

Widespread immunoreactivity for neuronal nuclei in cultured human and rodent astrocytes

The monoclonal antibody (mAb) neuronal nuclei (NeuN) labels the nuclei of mature neurons in vivo in vertebrates. NeuN has also been used to define post-mitotic neurons or differentiating neuronal precursors in vitro. In this study, we demonstrate that the NeuN mAb labels the nuclei of astrocytes cultured from fetal and adult human, newborn rat, and embryonic mouse brain tissue. A non-neuronal fibroblast cell line (3T3) also displayed NeuN immunoreactivity. We confirmed that NeuN labels neurons but not astrocytes in sections of P10 rat brain. Western blot analysis of NeuN immunoreactive species revealed a distribution of bands in nucleus-enriched fractions derived from the different cell lines that was similar, but not identical to adult rat brain homogenates. We then examined the hypothesis that the glial fibrillary acidic protein/NeuN-double positive population of cells might correspond to neuronal precursors. Although the NeuN-positive astrocytes were proliferating, no evidence of neurogenesis was detected. Furthermore, expression of additional neuronal precursor markers was not detected. Our results indicate that primary astrocytes derived from mouse, rat, and human brain express NeuN. Our findings are consistent with NeuN being a selective marker of neurons in vivo, but indicate that studies utilizing NeuN-immunoreactivity as a definitive marker of post-mitotic neurons in vitro should be interpreted with caution.

Egr-1-d2EGFP transgenic rats identify transient populations of neurons and glial cells during postnatal brain development

The inducible transcription factor Egr-1 has been extensively studied in the adult brain but potential roles during development are largely unexplored. Here we describe the analysis of a new transgenic rat model (egr-1 promoter driving a destabilized GFP molecule) that has provided novel information about the postnatal roles of Egr-1. We show that Egr-1 is more widely expressed in the neonatal brain than was previously appreciated, and is not restricted to neurons; it is expressed in glial cells in the postnatal neocortex and hippocampus. This pattern of expression has been revealed due to cellular filling by GFP, permitting co-localization with glial markers. The transgene/Egr-1 is also expressed in a novel population of cells associated with Cajal-Retzius-like neurons within the marginal zone of the postnatal neocortex. Both of these cellular populations are transient, being limited to the neonatal period, before Egr-1 expression becomes established in an adult-like pattern within neocortical neurons, CA1 hippocampus, and striatum. Another transient population of transgene/Egr-1 cells in the bed nucleus of the stria terminalis is maintained until pre-adolescence. The transient phenotype of these cells involves a low relative expression of the neuronal marker NeuN, perhaps indicating a failure to achieve full neuronal differentiation. Egr-1 is therefore present in a diverse range of cell-types during postnatal development. Transgenic expression of a destabilized fluorescent marker has permitted identification of these novel cell populations and will facilitate further analysis of the transcriptional mechanisms that underlie the specific functions and fate of these cells during postnatal brain development.

Allocation of paraventricular and supraoptic neurons requires Sim1 function: a role for a Sim1 downstream gene PlexinC1

SIM1 is a transcription factor essential for the developmental expression of the endocrine hormone genes, e.g. vasopressin (Vp) and oxytocin (Ot), in the paraventricular nucleus (PVN) and supraoptic nucleus (SON) of the hypothalamus. Mice mutant for Sim1 lack structural PVN and SON, attributed in previous studies to the death of the PVN/SON progenitor cells. Here, we use a tau-LacZ knock-in allele at the Sim1 locus to trace Sim1 mutant cells and show that they are generated normally and survive to birth, contrasting to the previous proposal. Mutant cells adopt neuronal characteristics and maintain their PVN/SON identity as they continue to express PVN/SON progenitor markers. However, they occupy an ectopic position between the normal PVN and SON, indicating a defect in neuronal migration. To explore candidate molecular cues that contribute to PVN/SON neuronal migration, we focused on the Plexin family of genes. We found that PlexinA1 is expressed in regions surrounding the PVN and SON, whereas PlexinC1 is expressed within the PVN and SON. PlexinA1 expression becomes up-regulated in Sim1 mutant cells, whereas PlexinC1 expression is down-regulated. Finally, the PlexinC1 mutant has a selective defect in partitioning the VP and OT neurons coherently into the PVN and SON. Together, our results uncover a transcriptional regulation of neuronal migration cues initiated by Sim1 that contribute to the organization of the PVN and SON.

Neuron death and inflammation in a rat model of intracerebral hemorrhage: Effects of delayed minocycline treatment

After intracerebral hemorrhage (ICH), blood entry is followed by neuron death and an inflammatory response, but development of pharmacological therapies has been hampered by an inadequate understanding of the spatial and temporal relationship between neuron death and inflammation. Using a rat model of ICH, we first investigated these relationships at 6 h, and 1, 3 and 7 days. At the edge of the hematoma, no degenerating neurons were observed at 6 h; however, dying neurons were present between 1 and 3 days, with peak neuron death occurring at 1 day. This is apparently the first report of ongoing neuron death at the edge of the hematoma during a time window that is appropriate for human therapy. Neuron death was limited to the edge of the hematoma, with no degenerating neurons in the striatum surrounding the hematoma, despite robust and prolonged microglia activation. Importantly, neuron loss at the edge of the hematoma was spatially and temporally associated with accumulation and activation of microglia/macrophages. We then tested the hypothesis that treatment with the tetracycline derivative, minocycline, after the hematoma had reached a maximal size, will reduce inflammation and neuron damage. Minocycline injection (45 mg/kg i.v. at 6 h, and i.p. at 24, 48 and 72 h) failed to reduce neuron loss outside the hematoma or striatal tissue loss (assessed at 7 days), despite reducing the number of neutrophils and activated microglia/macrophages. Thus, minocycline does not appear to target the mechanisms responsible for cell death in this model of ICH.

Detection of Bone Marrow-Derived Cells Expressing a Neural Phenotype in the Human Brain

Animal studies suggest that adult bone marrow cells have the potential to migrate into the brain and generate new neural cells. Because data on this physiologic repair mechanism in humans are lacking, we investigated bone marrow engraftment into the brain of bone marrow recipients after sex-mismatched transplantation. Brain sections of seven allogeneic female bone marrow recipients were examined. The Y-chromosome, which served as a natural marker of donor bone marrow-derived cells after male-to-female transplantation, was identified by in situ hybridization. The neural phenotype of Y-chromosome-positive cells was determined using neural nuclear protein (NeuN) immunohistochemistry. Y-chromosome-positive cells expressing NeuN were found within the first 3 months after transplantation in both the cerebrum and the cerebellum at a frequency of 0.003% to 0.013% of all neurons. These cells were observed only in patients with cerebral lymphocytic infiltration and graft-versus-host disease. Our data suggest that adult bone marrow cells are capable of generating cells that express the neural marker NeuN early after transplantation. Cells with this specific phenotype may contribute to tissue repair in brain regions remote from neurogenic zones.

Neuron-specific nuclear antigen NeuN is not detectable in gerbil subtantia nigra pars reticulata

NeuN (Neuronal Nuclei), the neuron-specific marker of nuclear protein is used extensively in histological procedures to identify major cell-types in adult vertebrate nervous systems of a variety of species including rodents and humans. Some notable exceptions (i.e., NeuN-negative neurons) include Purkinje cells in cerebellum, mitral cells in olfactory bulb, and photoreceptors in retina. Here we report that neurons in gerbil (Meriones unguiculatus) substantia nigra pars reticulata (SNr), whose "neuronal" phenotype was confirmed via electrophysiology, biocytin-labeling, histology, and in situ hybridization, are also devoid of NeuN-immunoreactivity as assayed with the widely used monoclonal antibody A60. Immunohistochemistry of rat SNr using the same antibody yielded robust staining. These data suggest lack of NeuN-immonoreactivity observed in certain cell-types and brain regions can be species-specific.

Immunohistochemical localization and biological activity of the steroidogenic enzyme cytochrome P450 17α-hydroxylase/C17, 20-lyase (P450C17) in the frog brain and pituitary

It is now clearly established that the brain has the capability of synthesizing various biologically active steroids including 17-hydroxypregnenolone (17OH-Delta(5)P), 17-hydroxyprogesterone (17OH-P), dehydroepiandrosterone (DHEA) and androstenedione (Delta(4)). However, the presence, distribution and activity of cytochrome P450 17alpha-hydroxylase/C17, 20-lyase (P450(C17)), a key enzyme required for the conversion of pregnenolone (Delta(5)P) and progesterone (P) into these steroids, are poorly documented. Here, we show that P450(C17)-like immunoreactivity is widely distributed in the frog brain and pituitary. Prominent populations of P450(C17)-containing cells were observed in a number nuclei of the telencephalon, diencephalon, mesencephalon and metencephalon, as well as in the pars distalis and pars intermedia of the pituitary. In the brain, P450(C17)-like immunoreactivity was almost exclusively located in neurons. In several hypothalamic nuclei, P450(C17)-positive cell bodies also contained 3beta-hydroxysteroid dehydrogenase-like immunoreactivity. Incubation of telencephalon, diencephalon, mesencephalon, metencephalon or pituitary explants with [(3)H]Delta(5)P resulted in the formation of several tritiated steroids including 17OH-Delta(5)P, 17OH-P, DHEA and Delta(4). De novo synthesis of C(21) 17-hydroxysteroids and C(19) ketosteroids was reduced in a concentration-dependent manner by ketoconazole, a P450(C17) inhibitor. This is the first detailed immunohistochemical mapping of P450(C17) in the brain and pituitary of any vertebrate. Altogether, the present data provide evidence that CNS neurons and pituitary cells can synthesize androgens.

Spatial exploration induces ARC, a plasticity-related immediate-early gene, only in calcium/calmodulin-dependent protein kinase II-positive principal excitatory and inhibitory neurons of the rat forebrain

Active behavior, such as exploring a novel environment, induces the expression of the immediate-early gene Arc (activity-regulated cytoskeletal associated protein, or Arg 3.1) in many brain regions, including the hippocampus, neocortex, and striatum. Arc messenger ribonucleic acid and protein are localized in activated dendrites, and Arc protein is required for the maintenance of long-term potentiation and memory consolidation. Although previous evidence suggests that Arc is expressed in neurons, there is no direct demonstration that only neurons can express Arc. Furthermore, there is no characterization of the main neuronal types that express Arc. The data reported here show that behavior- or seizure-induced Arc expression in the hippocampus, primary somatosensory cortex, and dorsal striatum of rats colocalizes only with neuronal (NeuN-positive) and not with glial (GFAP-positive) cells. Furthermore, Arc was found exclusively in non-GABAergic alpha-CaMKII-positive hippocampal and neocortical neurons of rats that had explored a novel environment. Some GAD65/67-positive neurons in these regions were observed to express Arc, but only after a very strong stimulus (electroconvulsive seizure). In the dorsal striatum, spatial exploration induced Arc only in GABAergic and alpha-CaMKII-positive neurons. Combined, these results show that although a very strong stimulus (seizure) can induce Arc in a variety of neurons, behavior induces Arc in the CaMKII-positive principal neurons of the hippocampus, neocortex, and dorsal striatum. These results, coupled with recent in vitro findings of interactions between Arc and CaMKII, are consistent with the hypothesis that Arc and CaMKII act as plasticity partners to promote functional and/or structural synaptic modifications that accompany learning.

Immunocytochemical detection of brain neurons using the selective marker NeuN

The aim of the present work was to develop optimal protocols for immunocytochemical reactions for nuclear protein NeuN for light and laser confocal microscopy which avoid the thermal antigen demasking procedure, which degrades the state of the tissue and requires use of expensive adhesive-coated slices. Maximal antigen retention was obtained after fixation in zinc-formalin and Bouin's fluid (maximum one day). Two protocols are proposed allowing the thermal demasking procedure to be avoided during detection of neuron marker NeuN on paraffin sections examined by light and confocal microscopy.

Chicken cerebellar granule neurons rapidly develop excitotoxicity in culture

Rat cerebellar granule cell culture is widely used as a model to study factors that control neuronal differentiation and death (e.g. excitotoxicity). However, a main drawback of this model is its dependence on depolarizing culture condition (25 mM potassium). In addition, it is quite expensive to maintain and requires animal facilities. Here we report that cerebellar granule neuron cultures from chicken may be used as an alternative model to study excitotoxicity. Surprisingly, fetal chicken cells may be grown in a physiological potassium concentration (5 mM potassium). They develop excitotoxicity rapidly in culture (fully developed at 3 days in vitro), and respond to glutamate excitotoxicity similar to rat cultures (ROS production and activation of caspase-3).

Developmental regulation of alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid receptor subunit expression in forebrain and relationship to regional susceptibility to hypoxic/ischemic injury. II. Human cerebral white matter and cortex

This report is the second of a two-part evaluation of developmental differences in alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid receptor (AMPAR) subunit expression in cell populations within white matter and cortex. In part I, we reported that, in rat, developmental expression of Ca2+-permeable (GluR2-lacking) AMPARs correlated at the regional and cellular level with increased susceptibility to hypoxia/ischemia (H/I), suggesting an age-specific role of these receptors in the pathogenesis of brain injury. Part II examines the regional and cellular progression of AMPAR subunits in human white matter and cortex from midgestation through early childhood. Similarly to the case in the rodent, there is a direct correlation between selective vulnerability to H/I and expression of GluR2-lacking AMPARs in human brain. For midgestational cases aged 20-24 postconceptional weeks (PCW) and for premature infants (25-37 PCW), we found that radial glia, premyelinating oligodendrocytes, and subplate neurons transiently expressed GluR2-lacking AMPARs. Notably, prematurity represents a developmental window of selective vulnerability for white matter injury, such as periventricular leukomalacia (PVL). During term (38-42 PCW) and postterm neonatal (43-46 PCW) periods, age windows characterized by increased susceptibility to cortical injury and seizures, GluR2 expression was low in the neocortex, specifically on cortical pyramidal and nonpyramidal neurons. This study indicates that Ca2+-permeable AMPAR blockade may represent an age-specific therapeutic strategy for potential use in humans. Furthermore, these data help to validate specific rodent maturational stages as appropriate models for evaluation of H/I pathophysiology.

Methodological aspects of 3D and automated 2D analyses of white matter neuronal density in temporal lobe epilepsy

White matter neuronal density has been correlated with clinical outcome after temporal lobectomy for refractory epilepsy. Both morphometric 2D (two-dimensional) and stereological 3D (three-dimensional) analyses of neuronal density have been performed. 3D analyses are thought to be more accurate than 2D counts, but more time-consuming. We compared 3D and automated 2D measurements in the same specimens. Adjacent 20-microm (for 3D analyses) and 5-microm (for 2D analyses) sections from 10 temporal lobectomies were stained for NeuN immunohistochemistry. Analysis of 100% of a region of interest (ROI) in deep white matter was performed using an image analysis system (Histometrix, Kinetic Imaging, UK). 3D analyses were undertaken using x 63 magnification (6 h/case). Automated 2D analyses were undertaken using automatic neuronal identification at x 10 magnification with three to four repeats (1.5 h/case). The range of neuronal densities for 3D measurements was 2120-4910 neurones/mm(3), and for automated 2D measurements 17.4-47.1 neurones/mm2. There was a linear correlation between the two methods with an r2 of 0.58. [corrected] Count-recount variability was 1.4-9.9% for the 3D and 5.1-36.6% for the automated 2D measurements. We found a wide range of white matter neuronal densities using either analysis. The low agreement between methods, and the high count-recount variability for the automated 2D analyses, indicate that despite being more time-consuming, rigorous 3D stereological analyses have to be performed to obtain reliable results. These findings have implications for studies requiring neuronal counts in normal and disease states.

Characterizing the Mitogenic Effect of Basic Fibroblast Growth Factor in the Adult Rat Striatum

The limited regenerative capacity of the adult central nervous system (CNS) renders it unable to fully recover from injury or disease. Although stem and progenitor cells have been shown to reside throughout the brain, in most regions they exist as quiescent cell populations and do not divide sufficiently to replace damaged or destroyed cells. In an effort to stimulate the proliferative capacity of these multipotent cells, we sought to determine the in vivo response of the adult CNS to an exogenous application of basic fibroblast growth factor (bFGF), a known mitogen to stem and progenitor cells. Specifically, we administered bFGF to the striatum of adult rats at varying concentrations (1, 10, 100, 1,000, or 10,000 ng/mL in saline) so as to establish a dose response curve for bFGF-induced cell proliferation. Forty-eight hours following bFGF administration, animals were injected with 5-bromodeoxyuridine to label dividing cells. Of the doses assessed, we found that 1,000 ng/mL bFGF generated the greatest proliferative response over that observed in animals given a control saline injection. Further, the proliferative response of the striatum to bFGF administration could be enhanced twofold by supplementing this growth factor with heparin sulfate, a factor that facilitates the binding of bFGF to its receptors. By determining the maturational fate of the proliferating cell population, we found that a significant proportion of newly generated cells resulting from bFGF administration differentiated into astrocytes. Collectively, these studies demonstrate the potential of bFGF to promote proliferation in the adult brain, which can be exploited to facilitate cell replacement therapies.

DNA damage and nonhomologous end joining in excitotoxicity: neuroprotective role of DNA-PKcs in kainic acid-induced seizures

DNA repair plays a critical, but imprecisely defined role in excitotoxic injury and neuronal survival throughout adulthood. We utilized an excitotoxic injury model to compare the location and phenotype of degenerating neurons in mice (strain 129-C57BL) deficient in the catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs), an enzyme required for nonhomologous end joining (NHEJ). Brains from untreated adult heterozygous and DNA-PKcs null mice displayed comparable cytoarchitecture and undetectable levels of cell death. By day 1, and extending through 4 days following kainic acid-induced seizures, brains from DNA-PKcs null mice showed widespread neurodegeneration that encompassed the entire hippocampal CA1-CA3 pyramidal cell layer, entorhinal cortex, and lateral septum, with relative sparing of the dentate gyrus granule cell layer and hilus, as judged by toluidine blue, Fluoro-Jade B, and terminal dUTP nick end labeling staining. In contrast, seizure-related neurodegeneration in heterozygous littermates was limited to the CA3 region of the hippocampus. NeuN and calbindin staining revealed a selective decrease in the number and density of NeuN-positive neurons in the pyramidal layers of degenerating regions in both heterozygous and DNA-PKcs null mice. To elucidate the mechanisms leading to cell death, we examined an involvement of the p53 pathway, known to be induced by DNA damage. Addition of pifithrin-alpha, a p53 inhibitor, or expression of a dominant-negative p53 rescued neurons from kainate-induced excitotoxic cell death in primary cortical cultures derived from wildtype, DNA-PKcs heterozygous, or DNA-PKcs null neonatal mice. Moreover, pifithrin-alpha prevented kainate-induced loss of mitochondrial membrane potential, dendrite degeneration, and cell death. Results suggest that NHEJ plays a neuroprotective role in excitotoxicity, within the perforant, Schaffer collateral, hippocampal-septal, and temperoammonic pathways, in part by repairing DNA damage that would otherwise result in activation of a p53-dependent apoptotic cascade.

Vesicular glutamate transporter 1 immunostaining in the normal and epileptic human cerebral cortex

Glutamate is the main excitatory neurotransmitter in the brain where, due to the activity of specific vesicular glutamate transporters, it accumulates in synaptic vesicles. The vesicular glutamate transporter 1 is found in the majority of axon terminals that form asymmetrical (excitatory) synapses in the rat neocortex. However, since there is no information available regarding the distribution of vesicular glutamate transporter 1 in the human neocortex, we have used correlative light and electron microscopy to define its expression in this tissue. We found that the distribution of vesicular glutamate transporter 1-immunoreactivity is virtually identical to that found in the rat neocortex, both at the light and electron microscope levels. Therefore, we assessed whether vesicular glutamate transporter 1 immunostaining might be a useful tool to study the pathological alterations of glutamatergic transmission in the epileptic cerebral cortex. We analyzed the distribution of vesicular glutamate transporter 1 in the peritumoral neocortex of patients with epilepsy secondary to low-grade tumors. In these regions, we found alterations in the pattern of vesicular glutamate transporter 1-immunoreactivity that perfectly matched the neuronal loss and gliosis, as well as the decrease in the number of asymmetrical synapses identified by electron microscopy in this tissue. Thus, vesicular glutamate transporter 1 immunostaining appears to be a reliable and simple tool to study glutamatergic synapses in the normal and epileptic human cerebral cortex.

Immunohistochemical visualization of neurons and specific glial cells for stereological application in the porcine neocortex

The pig is becoming an increasingly used non-primate model in basic experimental studies of human neurological diseases. In spite of the widespread use of immunohistochemistry and cell type specific markers, the application of immunohistochemistry in the pig brain has not been systematically described. Therefore, to facilitate future stereological studies of the neuronal and glial cell populations in experimental neurological diseases in the pig, we established a battery of immunohistochemical protocols for staining of perfusion fixed porcine brain tissue processed as free floating cryostat-, vibratome- or paraffin sections. Antibodies against NeuN, GFAP, S100-protein, MBP, CNPase, CD11b, CD68 (KP1), CD45 and Ki67 were evaluated, and all except CD68 and CD45 resulted in staining of high quality in either type of tissue. Each staining was evaluated with respect to specificity and sensitivity in identification of the individual cells, and for penetration of the staining and maintenance of section thickness above 25 microm, necessary for stereological cell counting. In the cases of NeuN, CNPase, CD11b and Ki67 the staining met the demands to be applicable in stereological analyses using the optical disector. In conclusion, all protocols will be applicable in studies of pathological and neurochemical changes in the porcine brain, and a few protocols applicable for stereology.

MeCP2 expression and function during brain development: implications for Rett syndrome's pathogenesis and clinical evolution

Most cases of Rett syndrome (RTT) are associated with mutations of the transcriptional regulator MeCP2. On the basis of molecular structure, ontogeny, and subcellular and regional distribution, MeCP2 appears to be a link between synaptic activity and neuronal transcription. Integrating data on MeCP2 neurobiology, RTT neurobiology, MeCP2 mutational patterns in RTT and other disorders, histone profiles of relevance to RTT, and genotype-phenotype correlations in RTT, we update here our synaptic hypothesis of RTT. We postulate that MeCP2 dysfunction leads to abnormal brain development through maladjustment of neuronal gene expression to synaptic and other extra-cellular signals, mainly during the critical period of synaptic maturation. RTT phenotype will develop, only if severe MeCP2 dysfunction is present during early neuronal differentiation. Two models are proposed for explaining general and regional neuronal abnormalities in RTT and the phenotypical outcome of MeCP2 dysfunction, respectively.

HUlip, a human homologue of unc-33-like phosphoprotein of Caenorhabditis elegans; Immunohistochemical localization in the developing human brain and patterns of expression in nervous system tumors

HUlip is a human homologue of a C. elegans gene, unc-33, that is developmentally regulated during maturation of the nervous system. HUlip is highly expressed only in the fetal brain and spinal cord, and is undetected in the adult brain. The purpose of this study was to investigate the pattern of hUlip expression in the developing human brain and nervous system tumors. Ten human brains at different developmental stages and 118 cases of nervous system tumor tissues were examined by immunohistochemistry. Twelve related tumor cell lines were also analyzed by northern blotting and immunoblotting. HUlip was expressed in late fetal and early postnatal brains; strongly in the neurons of the brain stem, basal ganglia/thalamus, and dentate gyrus of the hippocampus, and relatively weakly in the cerebral and cerebellar cortex. Among tumors, hUlip expression was easily detected in tumor cells undergoing neuronal differentiation such as ganglioneuroblastomas and ganglioneuromas. Furthermore, hUlip immunoreactivity was also found in various brain tumors showing neuronal differentiation: central neurocytomas (6 of 6 cases were positive), medulloblastomas (5/11), atypical teratoid rhabdoid tumor (1/1) and gangliogliomas (4/7). Some astrocytic tumors also showed weak positivity: astrocytomas (1 of 5 cases), anaplastic astrocytomas (2/5), and glioblastomas (3/11). Subependymal giant cell astrocytomas and subependymomas, which are of controversial histogenetic origin, showed strong hUlip immunoreactivity. The results of this study indicate that the expression of hUlip protein is distinctly restricted to the late fetal and early postnatal periods of human nervous system development and to certain subsets of nervous system tumors. The exact function of hUlip needs to be further clarified; yet the results of our study strongly imply that hUlip function is important in human nervous system development and its aberrant expression in various types of nervous system tumors suggests a role of hUlip as an oncofetal neural antigen.

NeuN expression correlates with reduced mitotic index of neoplastic cells in central neurocytomas

In the developing brain, neuronal differentiation is associated with permanent exit from the mitotic cycle. This raises the possibility that neuronal differentiation may suppress proliferative activity, even in neoplastic cells. As a first step towards understanding the relation between neuronal differentiation and mitotic cycling in brain tumours, we studied the expression of NeuN (a neuronal marker) and Ki-67 (a mitotic marker) by double-labelling immuno-fluorescence in 16 brain tumours with neuronal differentiation. The tumours included a series of 11 central neurocytomas, and five single cases of other tumour types. In the central neurocytomas, NeuN(+) cells had a 15-fold lower Ki-67 labelling index, on average, than did NeuN(-) cells (P < 0.01). In the other tumours (one extraventricular neurocytoma, one desmoplastic medulloblastoma, one olfactory neuroblastoma, one ganglioglioma and one anaplastic ganglioglioma), the Ki-67 labelling index was always at least fourfold lower in NeuN(+) cells than in NeuN(-) cells. These results indicate that neuronal differentiation is associated with a substantial decrease of proliferative activity in neoplastic cells of central neurocytomas, and suggest that the same may be true across diverse types of brain tumours. However, tumours with extensive neuronal differentiation may nevertheless have a high overall Ki-67 labelling index, if the mitotic activity of NeuN(-) cells is high. The correlation between NeuN expression and reduced mitotic activity in neurocytoma cells is consistent with the hypothesis that neuronal differentiation suppresses proliferation, but further studies will be necessary to determine causality and investigate underlying mechanisms.

Differentiation of classic medulloblastoma into metastatic large cell medulloblastoma with focal rhabdoid differentiation in the absence of posterior fossa recurrence

A case of classic medulloblastoma that metastasized, despite the absence of local recurrence, to extraneural sites 7 years after treatment is reported. The metastases were, in contrast to the primary tumor, of large cell type and displayed abortive myogenic and, in one site, also rhabdoid differentiation. The primary tumor expressed microtubule-associated protein 1B and neuron-specific nuclear protein (NeuN), and was desmin negative. The metastases were also positive for microtubule-associated protein 1B and NeuN, although the expression of the latter marker was weak and/or focal in two of four metastases and absent in the rhabdoid metastasis. They were, in contrast with the primary tumor, all strongly positive for desmin. The hSNF5/INI1 was expressed in the nuclei of all cells of the primary tumor and the metastases, including the one with rhabdoid differentiation. Two metastases were studied by cytogenetics. The composite karyotype of a large cell metastasis was 45~46,XY,add(1)(p36.1),t(2;8)(p21;q24.1),add(3)(q25),t(9;15)(q22;q13),add(12)(p11.2), +1approximately2mar,inc[cp12]/46,XY[12], while the rhabdoid metastasis contained additional changes including monosomy 22. These findings indicate that some rhabdoid (atypical teratoid/rhabdoid) tumors of the cerebellum and medulloblastoma may be histogenetically related.

Effects of prenatal alcohol exposure on the development of the vibrissal somatosensory cortical barrel network

We have previously shown that the serotonin (5-HT) and its thalamocortical afferents are compromised by prenatal alcohol exposure (PAE). The development of the sensory cortical barrels is regulated by 5-HT-rich thalamocortical afferents. Therefore, it is hypothesized that PAE will deleteriously affect the postnatal development of the cortical barrel formations. On embryonic day (E)7, C57BL/6 mice were grouped into: Alcohol (Alc), Pair-fed (PF), or Chow, and maintained on diet until E18. On postnatal day 7, cortices were stained with 5-HT for thalamocortical fibers, and a NeuN for identification of mature neurons. The area of the posterior medial barrel subfield (PMBSF), was measured as well as the number of NeuN+ neurons within the barrel patches. Though brain weight and brain volume were similar among the three groups, a significant reduction was seen in total area of the PMBSF, and in the average individual barrel area in the Alc group as compared to Chow. Furthermore, the volumes of the B, but not C row barrels were significantly reduced. Barrels were found missing in layer IV, specifically in the posterior aspects of the A, B, and straddler row in the Alc group. Cell counts demonstrated a nearly 50% reduction in NeuN+ neuron number in both rows. This reduction in size of the PMBSF and fewer neurons within these sensory barreloids may underlie a change in the development of the discriminatory sensitivity of the whiskers and serves as an excellent model for the study of a compromised sensory modality following PAE.

A mesenchyme-free culture system to elucidate the mechanism of otic vesicle morphogenesis

The vertebrate inner ear has been extensively studied as a model system of morphogenesis and differentiation. The interactions between epithelium and surrounding mesenchyme have not previously been studied directly, because an appropriate experimental system had not been established. Here we describe a mesenchyme-free culture system of E11.5 mouse otic vesicle which retains the ability for (1) formation of the cochlear loop, (2) emigration of ganglion cells from the epithelium and (3) invagination of semicircular canal epithelium. E10.5 otic vesicle was maintained using the same method, but morphogenesis was less successful. Culture of the E11.5 cochlear region alone resulted in regeneration of a structure with semicircular canal character from the cut end, indicating that region-specific cell fate within the otic vesicle is not irreversibly determined at this stage. Co-culturing otic vesicle with cochleovestibular ganglion (CVG) resulted in enhanced looping or ectopic diverticulum formation of the cochlear region, suggesting that the CVG provides a morphogenetic signal for cochlear looping. Cochlear looping was specifically blocked by inhibiting actin polymerization by cytochalasin D, while morphogenesis of the semicircular canal region remained intact. Hyaluronidase treatment inhibited semicircular canal morphogenesis, resulting in a cystic form of the otic vesicle. These data validate this culture system as a tool for elucidating the mechanism of morphogenesis of the otic vesicle.

Spontaneous recurrent seizure following status epilepticus enhances dentate gyrus neurogenesis

It is known that evoked seizures can increase neurogenesis in the dentate gyrus in adult rats. Whether spontaneous seizures occurring after status epilepticus (SE) also results in alterations in neurogenesis is not known. Here, we measured neurogenesis in rats with and without spontaneous seizures following SE. Lithium-pilocarpine was used to induce seizures in postnatal (P) day 20 rats. Spontaneous seizure frequency was assessed 2 months using video monitoring. Rats then received bromodeoxyuridine to label dividing DNA and were sacrificed 24 h later. Animals with spontaneous seizures (n = 9) had a modest increase in neurogenesis compared to animals with SE (n = 6) and no spontaneous seizures and control rats (n = 10). These findings demonstrate that the hippocampus is capable of generating new neurons weeks following SE and further that recurrent seizures enhance the production of new neurons. These alterations in neurogenesis may contribute to ongoing pathological changes week and months following SE.

Adult bone marrow stromal cells in the embryonic brain: engraftment, migration, differentiation, and long-term survival

We recently differentiated adult rat and human bone marrow stromal cells (MSCs) into presumptive neurons in cell culture. To determine whether the MSCs assume neuronal functions in vivo, we now characterize for the first time engraftment, migration, phenotypic expression, and long-term survival after infusion into embryonic day 15.5 (E15.5) rat ventricles in utero. By E17.5, donor cells formed discrete spheres in periventricular germinal zones, suggesting preferential sites of engraftment. The cells expressed progenitor vimentin and nestin but not mature neuronal markers. By E19.5, a subset assumed elongated migratory morphologies apposed to radial nestin-positive fibers running through the cortical white matter and plate, suggesting migration along radial glial processes. Cells remaining in germinal zones extended long, vimentin-positive fibers into the parenchyma, suggesting that the MSCs generated both migratory neurons and guiding radial glia. Consistent with this suggestion, >50% of cultured mouse MSCs expressed the neuroprecursor/radial glial protein RC2. From E19.5 to postnatal day 3, MSCs populated distant areas, including the neocortices, hippocampi, rostral migratory stream, and olfactory bulbs. Whereas donor cells confined to the subventricular zone continued to express nestin, cells in the neocortex and midbrain expressed mature neuronal markers. The donor cells survived for at least 2 months postnatally, the longest time examined. Confocal analysis revealed survival of thousands of cells per cubic millimeter in the frontal cortex and olfactory bulb at 1 month. In the cortex and bulb, 98.6 and 77.3% were NeuN (neuronal-specific nuclear protein) positive, respectively. Our observations suggest that transplanted adult MSCs differentiate in a regionally and temporally specific manner.

Adult bone marrow stromal cells in the embryonic brain: engraftment, migration, differentiation, and long-term survival

We recently differentiated adult rat and human bone marrow stromal cells (MSCs) into presumptive neurons in cell culture. To determine whether the MSCs assume neuronal functions in vivo, we now characterize for the first time engraftment, migration, phenotypic expression, and long-term survival after infusion into embryonic day 15.5 (E15.5) rat ventricles in utero. By E17.5, donor cells formed discrete spheres in periventricular germinal zones, suggesting preferential sites of engraftment. The cells expressed progenitor vimentin and nestin but not mature neuronal markers. By E19.5, a subset assumed elongated migratory morphologies apposed to radial nestin-positive fibers running through the cortical white matter and plate, suggesting migration along radial glial processes. Cells remaining in germinal zones extended long, vimentin-positive fibers into the parenchyma, suggesting that the MSCs generated both migratory neurons and guiding radial glia. Consistent with this suggestion, >50% of cultured mouse MSCs expressed the neuroprecursor/radial glial protein RC2. From E19.5 to postnatal day 3, MSCs populated distant areas, including the neocortices, hippocampi, rostral migratory stream, and olfactory bulbs. Whereas donor cells confined to the subventricular zone continued to express nestin, cells in the neocortex and midbrain expressed mature neuronal markers. The donor cells survived for at least 2 months postnatally, the longest time examined. Confocal analysis revealed survival of thousands of cells per cubic millimeter in the frontal cortex and olfactory bulb at 1 month. In the cortex and bulb, 98.6 and 77.3% were NeuN (neuronal-specific nuclear protein) positive, respectively. Our observations suggest that transplanted adult MSCs differentiate in a regionally and temporally specific manner.

Epidermal growth factor-induced cell proliferation in the adult rat striatum

Current strategies for repairing the adult CNS following injury include cell transplantation and/or the use of viral vectors to deliver therapeutic agents. Although promising, both techniques are limited in their usefulness due to the immunological response triggered in the brain as a result of the introduction of foreign antigens. An alternative method to repair the damaged CNS is to stimulate endogenous cells within the brain to divide thereby replacing cells lost to injury. Since it has been shown that growth factors such as epidermal growth factor (EGF) are potent mitogens to CNS cells in vitro, we sought to assess the mitogenic effect of an in vivo application of EGF to the adult mammalian brain. Accordingly, varying doses of human recombinant EGF were administered to the striatum of adult rats, followed 48 h later by intraperitoneal injections of 5-bromodeoxyuridine (BrdU), a marker for cell proliferation. Of four doses assessed, 0.05 ng of EGF induced the highest levels of cell proliferation. To determine the cellular identity of these proliferating cells, animals were injected with (3)H-thymidine 48 h following EGF administration to label dividing cells. Sections were subsequently immunostained for markers to astrocytes, microglia, oligodendrocytes, neural precursors, and mature neurons. Compared to controls, a significant proportion of the newly generated cells resulting from EGF administration were identified as immature and mature astrocytes. Collectively, these results provide valuable information for utilizing a growth factor administration approach to mobilize the proliferative response of endogenous cells to replace those lost to injury or disease.

Transformation of human umbilical mesenchymal cells into neurons in vitro

Neuronal transplantation has provided a promising approach for treating neurodegenerative diseases. Recently, efforts have been directed at in vitro induction of various stem cells to transform into neurons. We report the first successful quantities in an in vitro attempt at directing the transformation into neurons of human umbilical mesenchymal cells, which are capable of rapid proliferation in vitro and are easily available. When cultured in neuronal conditioned medium, human umbilical mesenchymal cells started to express neuron-specific proteins such as NeuN and neurofilament (NF) on the 3rd day and exhibited retraction of the cell body, elaboration of processes, clustering of cells and expression of functional mRNA responsible for the synthesis of subunits of the kainate receptor and glutamate decarboxylase on the 6th day. Between the 9th and 12th days, the percentage of human umbilical mesenchymal cells expressing NF was as high as 87%, while functionality was demonstrated by glutamate invoking an inward current. At this stage, cells were differentiated into mature neurons in the post mitosis phase.

Loss of NeuN immunoreactivity after cerebral ischemia does not indicate neuronal cell loss: a cautionary note

NeuN immunoreactivity is used as a specific marker for neurons. The number of NeuN-positive cells decreases under pathological conditions. This finding is usually considered as an evidence of neuronal loss. However, decrease in NeuN labeling may also be caused by depletion of the protein or loss of its antigenicity. Hence, we have investigated the morphological features of neurons that lost NeuN immunoreactivity and the NeuN protein levels in mouse brain after cerebral ischemia. The number of NeuN-labeled cells was decreased 6 h after a mild ischemic insult (30 min middle cerebral artery occlusion) in penumbral and core regions. Hematoxylin and eosin (H&E) staining of adjacent sections showed that neurons in the penumbra were not disintegrated but displayed early ischemic changes. The nuclear NeuN staining was dramatically reduced or lost in some neurons. However, Hoechst 33258 staining of the same sections revealed that these nuclei were preserved with an intact membrane. Labeling of neurons that had lost NeuN-positivity with antibodies against caspase-3-p20, which is constitutively not present but emerges in neurons after ischemia, disclosed that these neurons still preserved their integrity. Moreover, Western blots showed that NeuN protein levels were not decreased, suggesting that reduced NeuN antigenicity accounted for loss of immunoreactivity in this mild brain injury model. Supporting this idea, NeuN labeling was partially restored after antigenic retrieval. In conclusion, since NeuN immunoreactivity readily decreases after metabolic perturbations, reduced NeuN labeling should not be taken as an indicator of neuronal loss and, quantitative analysis based on NeuN-positivity should be used cautiously after central nervous system (CNS) injury.

Characterization of long-term mouse brain aggregating cultures: Evidence for maintenance of neural precursor cells

An extensive characterization of fetal mouse brain cell aggregates has been performed using immunohistochemical and stereological methods. Single cell suspensions from mechanically dissociated cortex and hippocampus were cultured in serum-free, B27-supplemented medium under constant gyratory agitation for up to 56 days. Three-dimensional aggregates started to form immediately after seeding and reached a final average size of 500 microm in diameter. Among the cell types identified, neurons were the most abundant cells in the aggregates, followed by astrocytes, microglia, and oligodendrocytes. Western blotting for synaptophysin and immunostaining for neurotransmitter-related molecules indicated the presence of well-defined phenotypic characteristics of the neurons in this culture system, suggesting functionality. Proliferating cells, many with neural precursor cell properties, were seen throughout the culture period and could be isolated from the aggregates even after 2 months in culture. Neural precursor cells were isolated from the aggregates after more than 1 month in culture; these cells were successfully differentiated into neurons, astrocytes, and oligodendrocytes. The aggregate culture system may provide a versatile tool for molecular dissection of processes identified in mouse models, including transgenic animals and manipulation of neural precursor cells.

Neuronal density, size and shape in the human anterior cingulate cortex: a comparison of Nissl and NeuN staining

There are an increasing number of quantitative morphometric studies of the human cerebral cortex, especially as part of comparative investigations of major psychiatric disorders. In this context, the present study had two aims. First, to provide quantitative data regarding key neuronal morphometric parameters in the anterior cingulate cortex. Second, to compare the results of conventional Nissl staining with those observed after immunostaining with NeuN, an antibody becoming widely used as a selective neuronal marker. We stained adjacent sections of area 24b from 16 adult brains with cresyl violet or NeuN. We measured the density of pyramidal and non-pyramidal neurons, and the size and shape of pyramidal neurons, in laminae II, III, Va, Vb and VI, using two-dimensional counting methods. Strong correlations between the two modes of staining were seen for all variables. However, NeuN gave slightly higher estimates of neuronal density and size, and a more circular perikaryal shape. Brain pH was correlated with neuronal size, measured with both methods, and with neuronal shape. Age and post-mortem interval showed no correlations with any parameter. These data confirm the value of NeuN as a tool for quantitative neuronal morphometric studies in routinely processed human brain tissue. Absolute values are highly correlated between NeuN and cresyl violet stains, but cannot be interchanged. NeuN may be particularly useful when it is important to distinguish small neurons from glia, such as in cytoarchitectural studies of the cerebral cortex in depression and schizophrenia.

Marrow stromal cells, mitosis, and neuronal differentiation: stem cell and precursor functions

To define relationships among marrow stromal cells (MSCs), multipotential progenitors, committed precursors, and derived neurons, we examined differentiation, mitosis, and apoptosis in vitro. Neural induction medium morphologically converted over 70% of MSCs to typical neurons, which expressed tau, neuronal nuclear antigen, neuron-specific enolase, and TUC-4 within 24 hours. A subset decreased fibronectin expression, consistent with mesenchymal to neuroectodermal conversion. More than 35% of differentiating neurons incorporated bromodeoxyuridine (BrdU) and divided, increasing cell number by 60%, while another subpopulation differentiated without incorporating BrdU or dividing. Inhibition of mitosis and DNA synthesis did not prevent neural differentiation, with 70% of blocked cells expressing tau and displaying neuronal morphologies. By deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling assay, less than 1% of cells underwent apoptosis at 36 and 72 hours, suggesting differentiation without cell-selective mechanisms. Apparently, MSCs may directly differentiate into neurons without passing through a mitotic stage, suggesting that distinctions among stem cells, progenitors, and precursors are more flexible than formerly recognized.

Class III beta-tubulin isotype: a key cytoskeletal protein at the crossroads of developmental neurobiology and tumor neuropathology

The expression of the cytoskeletal protein class III beta-tubulin isotype is reviewed in the context of human central nervous system development and neoplasia. Compared to systemic organs and tissues, class III beta-tubulin is abundant in the brain, where it is prominently expressed during fetal and postnatal development. As exemplified in cerebellar neurogenesis, the distribution of class III beta-tubulin is neuron associated, exhibiting different temporospatial gradients in the neuronal progeny of the external granule layer versus the neuroepithelial germinal matrix of the velum medullare. However, transient expression of this protein is also present in the telencephalic subventricular zones comprising putative neuronal and/or glial precursor cells. This temporospatially restricted, potentially non-neuronal expression of class III beta-tubulin may have implications in the accurate identification of presumptive neurons derived from transplanted embryonic stem cells. In the adult central nervous system, the distribution of class III beta-tubulin is almost exclusively neuron specific. Altered patterns of expression are noted in brain tumors. In "embryonal"-type neuronal/neuroblastic tumors of the central nervous system, such as the medulloblastomas, class III beta-tubulin expression is associated with neuronal differentiation and decreased cell proliferation. In contrast, the expression of class III beta-tubulin in gliomas is associated with an ascending grade of histologic malignancy and with correspondingly high proliferative indices. Thus, class III beta-tubulin expression in neuronal or neuroblastic tumors is differentiation dependent, whereas in glial tumors, it is aberrant and/or represents "dedifferentiation" associated with the acquisition of glial progenitor-like phenotype(s). From a diagnostic perspective, the detection of class III beta-tubulin immunostaining in neoplastic cells should not be construed as categorical evidence of divergent neuronal differentiation in tumors, which are otherwise phenotypically glial. Because class III beta-tubulin is present in neoplastic but not in normal differentiated glial cells, the elucidation of molecular mechanisms responsible for the altered expression of this isotype may provide critical insights into the dynamics of the microtubule cytoskeleton in the growth and progression of gliomas.

Hemimegalencephaly: part 2. Neuropathology suggests a disorder of cellular lineage

Cerebral tissue from hemispherectomy in three children (two 4-month-old girls and one 4-year-old boy) with hemimegalencephaly was studied using histochemical and immunocytochemical markers of neuronal and glial maturation and identity. Histologic abnormalities of cellular growth and cytomorphology, including "balloon cells," were present in both gray and white matter, in addition to disorganized tissue architecture. Cells in the mitotic cycle were absent. Many hypertrophic, atypical cells with enlarged processes exhibited mixed or ambiguous lineage, with immunoreactivity for both glial (glial fibrillary acidic protein [GFAP]; S-100beta) and neuronal proteins (microtubule-associated protein 2 [MAP2], neuronal nuclear antigen, chromogranin A, and neurofilament protein [NFP]). Strong vimentin reactivity was present in neurons, as well as glial cells and cells of mixed lineage, suggesting incomplete maturation. Synaptophysin-reactive axons terminated on a minority of balloon cells and on most heterotopic single neurons in white matter, confirmed by electron microscopy, demonstrating that single heterotopic neurons are not synaptically "isolated," as they may appear; thus, they are capable of contributing to epilepsy. Oligodendrocytes are the least affected cells, at least in some cases. The findings are reminiscent of the hamartomas of tuberous sclerosis. We conclude that hemimegalencephaly is a primary disorder of neuroepithelial lineage and cellular growth. A migratory disturbance contributes to disorderly tissue architecture but is secondary. No pathologic difference is detected between isolated and syndromic forms of hemimegalencephaly.

Medulloblastoma tumorigenesis diverges from cerebellar granule cell differentiation in patched heterozygous mice

Medulloblastoma is a cerebellar tumor that can arise through aberrant activation of Sonic hedgehog (Shh) signaling, which normally regulates cerebellar granule cell proliferation. Mutations of the Shh receptor PATCHED (PTCH) are associated with medulloblastomas, which have not been found to have loss of PTCH heterozygosity. We address whether patched (Ptc) heterozygosity fundamentally alters granule cell differentiation and contributes to tumorigenesis by increasing proliferation and/or decreasing apoptosis in Ptc+/- mice. Our data show that postnatal Ptc+/- mouse granule cell precursor growth is not globally altered. However, many older Ptc+/- mice display abnormal cerebellar regions containing persistently proliferating granule cell precursors. Since fewer Ptc+/- mice form medulloblastomas, these granule cell rests represent a developmentally disrupted, but uncommitted stage of tumorigenesis. Although Ptc+/- mouse medulloblastomas express neurodevelopmental genes, they diverge from granule cell differentiation in their discordant coexpression of postmitotic markers despite their ongoing growth. Like human medulloblastomas, mouse tumors with reduced levels of the neurotrophin-3 receptor, trkC/Ntrk3, display decreased apoptosis in vivo, illustrating the role of TrkC in regulating tumor cell survival. These results indicate that Ptc heterozygosity contributes to tumorigenesis by predisposing a subset of granule cell precursors to the formation of proliferative rests and subsequent dysregulation of developmental gene expression.

Developmental and cell type-specific expression of the neuronal marker NeuN in the murine cerebellum

NeuN is a 46/48-kD nuclear protein antigen used widely to identify postmitotic neurons in both research and diagnostics. It is expressed by neurons throughout the nervous system of a variety of species, including birds, rodents, and man (Mullen et al. [1992] Development 116:201-211). When we sought to use NeuN to follow the developmental progression of murine cerebellar interneurons, we observed that expression of this antigen in the cerebellum was restricted to granule neurons and a small population of cells present in the lower molecular layer of the adult cerebellum. In an attempt to identify these cells, we combined immunostaining for NeuN with a panel of cell type-specific markers to unambiguously identify neurons that express NeuN in the adult and developing cerebellum. In contrast to postmitotic granule neurons, NeuN was not expressed by any other immunocytochemically identified cerebellar interneurons, which comprised basket and stellate cells, Golgi neurons, unipolar brush cells, and Lugaro cells. NeuN-positive cells in the molecular layer failed to express any cell type-specific markers tested. They may represent ectopic granule cells; alternatively, they may represent a hitherto unknown population of cerebellar cells. In vitro experiments suggest that NeuN expression is related closely to granule cell axogenesis. This approach also revealed that the level of NeuN expression could be modulated by chronically depolarizing these cells. Thus, whereas NeuN expression per se is a reliable marker of proliferative capacity, levels of NeuN expression may also be indicative of the physiological status of a postmitotic neuron.

Neuronal Nuclear Antigen (NeuN): A New Tool in the Diagnosis of Central Neurocytoma

The use of neuronal nuclear antigen (NeuN) as a reliable neuronal marker in the differential diagnosis of clear cell neoplasms of the central nervous system was determined in a biopsy series of 23 cases. Immunohistochemical analyses were carried out by antisera against neuronal nuclear antigen, synaptophysin, neuron-specific enolase, microtubule-associated protein 2, and glial fibrillary acidic protein. All eight central neurocytomas were characteristically immunolabeled by NeuN. NeuN immunoreactivity was uniformly strong and basically located in the nuclei of neurocytes. Despite this uniform staining pattern of central neurocytomas, 12 cases of oligodendrogliomas and three cases of ependymoma were negative for NeuN. As the diagnostic criteria for central neurocytoma include immunohistochemical and/or ultrastructural evidence for neuronal differentiation, NeuN as a sensitive and specific neuronal marker in formalin-fixed, paraffin-embedded tissues may greatly facilitate the differential diagnosis of central neurocytomas.