Application of single-cell microfluorimetry to neurotoxicology assays.

Intracellular signaling events play fundamental roles in regulating physiological function. In neurons, these include inducing growth and differentiation, secretion, gene expression, and controlling processes associated with learning and memory. All of these processes have in common the vital dependence on changes in intracellular Ca²(+) [Ca²(+)](i). Numerous toxicants, including metals, polychlorinated biphenyls, and biological neurotoxins, can disrupt [Ca²(+)](i). Understanding how toxicants disrupt Ca²(+)-dependent neuronal signaling, and thus induce neuronal death or dysfunction, requires the ability to monitor [Ca²(+)](i) at the level of individual cells. A series of fluorophores that can report on changes in [Ca²(+)](i) has been pivotal in this process. This section describes how to use these fluorophores to study effects of neurotoxicants on two types of processes: changes in [Ca²(+)](i) in individual cells and changes in mitochondrial membrane potential. Similar techniques using distinct fluorophores can be applied to other physiological processes.

Immortalized neural stem cells differ from nonimmortalized cortical neurospheres and cerebellar granule cell progenitors.

Pluripotent neural stem cells (NSCs) have been used as replacement cells in a variety of neurological disease models. Among the many different NSCs that have been used to date, most robust results have been obtained with the immortalized neural stem cell line (C17.2) isolated from postnatal cerebellum. However, it is unclear if other NSCs isolated from different brain regions are similar in their potency as replacement therapies. To assess the properties of NSC-like C17.2 cells, we compared the properties of these cells with those reported for other NSC populations identified by a variety of different investigators using biological assays, microarray analysis, RT-PCR, and immunocytochemistry. We show that C17.2 cells differ significantly from other NSCs and cerebellar granule cell precursors, from which they were derived. In particular, they secrete additional growth factors and cytokines, express markers that distinguish them from other progenitor populations, and do not maintain karyotypic stability. Our results provide a caution on extrapolating results from C17.2 to other nonimmortalized stem cell populations and provide an explanation for some of the dramatic effects that are seen with C17.2 transplants but not with other cells. We suggest that, while C17.2 cells can illustrate many fundamental aspects of neural biology and are useful in their own right, their unique properties cannot be generalized.

Sox2 expression defines a heterogeneous population of neurosphere-forming cells in the adult murine brain.

The identification of neural stem cells (NSCs) in situ has been prevented by the inability to identify a marker consistently expressed in all adult NSCs and is thus generally accomplished using the in vitro neurosphere-forming assay. The high-mobility group transcription factor Sox2 is expressed in embryonic neural epithelial stem cells; because these cells are thought to give rise to the adult NSC population, we hypothesized that Sox2 may continue to be expressed in adult NSCs. Using Sox2:EGFP transgenic mice, we show that Sox2 is expressed in neurogenic regions along the rostral-caudal axis of the central nervous system throughout life. Furthermore, all neurospheres derived from these neurogenic regions express Sox2, suggesting that Sox2 is indeed expressed in adult NSCs. We demonstrate that NSCs are heterogeneous within the adult brain, with differing capacities for cell production. In vitro, all neurospheres express Sox2, but the expression of markers common to early progenitor cells within individual neurospheres varies; this heterogeneity of NSCs is mirrored in vivo. For example, both glial fibrillary acidic protein and NG2 are expressed within individual neurospheres, but their expression is mutually exclusive; likewise, these two markers show distinct staining patterns within the Sox2+ regions of the brain's neurogenic regions. Thus, we propose that the expression of Sox2 is a unifying characteristic of NSCs in the adult brain, but that not all NSCs maintain the ability to form all neural cell types in vivo.

Disruption of intraneuronal divalent cation regulation by methylmercury: are specific targets involved in altered neuronal development and cytotoxicity in methylmercury poisoning?

Methylmercury is an environmental contaminant which causes relatively specific degeneration of the granular layer of the cerebellum, despite its ability to bind thiol groups in proteins of all cell types. The mechanisms underlying the specific targeting of cells during MeHg poisoning may depend on specific receptors and other targets related to divalent cation homeostasis, particularly intracellular calcium (Ca(2+)(i) signaling. MeHg disrupts Ca(2+)(i) homeostasis in a number of neuronal models, including cerebellar granule cells in primary culture, and contributes to MeHg-induced cell death, impaired synaptic function and disruption of neuronal development. Interestingly, the disruption of [Ca(2+)](i) regulation occurs through specific pathways which affect Ca(2+) regulation by organelles, particularly mitochondria and the smooth endoplasmic reticulum (SER). Cholinergic pathways which affect [Ca(2+)](i) signaling also appear to be critical targets, particularly muscarinic acetylcholine (ACh) receptors which are linked to Ca(2+) release through inositol-1,4,5-triphosphate (IP(3)) receptors. [Ca(2+)](i) dysregulation may also underlie observed alterations in cerebellar neuron development through interaction with specific target(s) in the developing axon. In this review, we examine the hypothesis that MeHg affects specific targets to cause disruption of neuronal development and cell death.

Acute exposure to methylmercury causes Ca2+ dysregulation and neuronal death in rat cerebellar granule cells through an M3 muscarinic receptor-linked pathway.

Acute exposure to low concentrations of methylmercury (MeHg) causes a severe loss of intracellular calcium (Ca2+(i)) homeostasis, which apparently contributes to neuronal death of cerebellar granule cells in culture. We examined the role of muscarinic receptors in MeHg-induced Ca2+ dysregulation and cell death in rat cerebellar granule cells in vitro using fura-2 single-cell microfluorimetry and viability assays, respectively. The nonspecific muscarinic receptor antagonist atropine significantly delayed the onset of MeHg-induced Ca2+ elevations and reduced the amount of Ca2+ released into the cytosol. Depletion of the smooth endoplasmic reticulum (SER) Ca2+ pool with thapsigargin or down-regulation of muscarinic receptors and inositol-1,3,4-triphosphate (IP3) receptors with bethanechol (BCh) caused similar reductions in the amplitude of the MeHg-induced Ca2+ increase, suggesting that MeHg interacts with muscarinic receptors to cause Ca2+ release from the SER through activation of the IP3 receptors. To determine whether this Ca2+ release plays a role in MeHg-induced cell death, cells were exposed to MeHg in the presence of specific muscarinic receptor inhibitors. Acute exposure to increasing concentrations of MeHg (0.2-1.0 microM) caused a corresponding increase in cell death at 24.5 h post-exposure. Prior down-regulation of muscarinic and IP3receptors with BCh protected against cell death. Protection was ablated by atropine and the M3 receptor antagonist 4-diphenylacetoxyl-N-methylpiperidine methiodide (DAMP), but not by the neuronal nicotinic receptor antagonist dihydro-beta-erythroidine hydrobromide (DHE). Thus activation of M3 muscarinic receptors with subsequent generation of IP3 evidently contributes to elevated [Ca2+]i and subsequent cytotoxicity of cerebellar granule cells by MeHg.

Distinguishing features of progenitor cells in the late embryonic and adult hippocampus.

Adult neurogenesis occurs within the subgranular layer of the hippocampal dentate gyrus. In this study, we examined dividing cells in the late embryonic and adult rat hippocampus to identify distinguishing characteristics and potential neural stem cell population(s), as identified by the putative neural stem cell markers FGFR4 and Sox1. In embryonic hippocampal cells in primary culture, basic fibroblast factor caused cell proliferation, increased telomerase activity and upregulation of FGFR4 mRNA. In both the embryonic and adult brains, proliferating cells express Sox1, as well as markers for neuronal- and glial-restricted precursors. However, the cell markers associated with cells expressing proliferative cell nuclear antigen (PCNA) and Sox1 differed between late embryonic and adult hippocampus, suggesting that there are important differences between adult and embryonic neurogenesis.

Identifying and tracking neural stem cells.

Hematopoietic stem cells, unlike neural stem cells, can be readily identified and isolated from developing and adult cell populations using positive and negative selection criteria. Isolating stem cells and progenitor cells from neural tissue has been more difficult because of difficulties in separating cells in solid tissue, the limited numbers of stem cells that persist in the adult, and the paucity of rigorously characterized markers. Nevertheless, strategies that have worked successfully in hematopoietic stem cell isolation can be adapted to isolate multiple classes of stem and progenitor cells from neural tissue. Neural stem cells also share cellular and molecular properties with other stem cell populations that may serve as surrogate identifiers of multipotentiality. Such potential markers are described. Unlike hematopoietic stem cells, tracking neural cells after transplantation is both necessary and more difficult. It will therefore be necessary to develop invasive and non-invasive strategies to follow transplanted cells and develop useful quantifiable readouts. Some potential strategies are described and current results are discussed.

Evidence for interactions between intracellular calcium stores during methylmercury-induced intracellular calcium dysregulation in rat cerebellar granule neurons.

Acute exposure to methylmercury (MeHg) causes severe disruption of intracellular Ca(2+) ([Ca(2+)](i)) regulation, which apparently contributes to neuronal death. Activation of the mitochondrial permeability transition pore (MTP) evidently contributes to this effect. We examined in more detail the contribution of mitochondrial Ca(2+) ([Ca(2+)](m)) to elevations of [Ca(2+)](i) caused by acute exposure to a low concentration of MeHg in primary cultures of rat cerebellar granule neurons. In particular, we sought to determine whether interactions occurred between Ca(2+)(i) pools in response to MeHg. Prior depletion of Ca(2+)(m) using carbonyl cyanide m-chlorophenylhydrazone (CCCP) and oligomycin significantly decreased the amplitude of [Ca(2+)](i) release from intracellular stores, and delayed the onset of whole-cell [Ca(2+)](i) elevations, caused by 0.5 microM MeHg. CCCP alone hastened the MeHg-induced release of Ca(2+) within the cell, whereas oligomycin alone delayed the MeHg-induced influx of extracellular Ca(2+). In granule cells loaded with rhod-2 acetoxymethylester to measure changes in [Ca(2+)](m), MeHg exposure caused a biphasic increase in fluorescence. The initial increase in fluorescence occurred in the absence of extracellular Ca(2+) and was abolished by mitochondrial depolarization. The secondary increase was associated with spreading of the dye from punctate staining to whole-cell distribution, and was delayed significantly by the MTP inhibitor cyclosporin A and the smooth endoplasmic reticulum Ca(2+) ATPase inhibitor thapsigargin. We conclude that MeHg causes release of Ca(2+) from the mitochondria through opening of the MTP, which contributes the bulk of the elevated [Ca(2+)](i) observed during MeHg neurotoxicity. Additionally, the Ca(2+) that enters the mitochondria seems to originate in the smooth endoplasmic reticulum, providing a mechanism for the observed mitochondrial Ca(2+) overload.

Neural stem cell therapy in the aging brain: pitfalls and possibilities.

As aging progresses, there is a decline in the brain's capacity to produce new neurons in the two neurogenic regions, the subventricular zone surrounding the lateral ventricles and the subgranular layer of the hippocampal dentate gyrus. The underlying cause of the declining neurogenesis is unknown, but is presumably related to age-related changes that occur during normal aging of the brain. It is exacerbated by age-related neurodegenerative diseases such as Alzheimer's and Parkinson's diseases. Stem cell-based therapy to replace lost and/or damaged cells in the aging brain is currently the focus of intense research. The two most promising approaches involve transplantation of exogenous tissue and promoting proliferation of endogenous cells. However, age-related changes in the brain environment, including elevated oxidative stress and accumulation of protein and lipid by-products, present several unique challenges that must be addressed before cell-based therapy can be used as a viable option. Although progress has been made toward replacement of lost cells and recovery of lost function, there are fundamental issues that need to be addressed for stem cell therapy to be successful in the aging brain. In this review, we focus on recent progresses made toward understand the biology of neural stem cells in the aging brain, as well as progress toward using stem cells to replace cells lost during disease.

Acute exposure to methylmercury opens the mitochondrial permeability transition pore in rat cerebellar granule cells.

Cerebellar granule cells are preferentially targeted during methylmercury (MeHg) poisoning. Following acute MeHg exposure, granule cells in culture undergo an increase in intracellular Ca2+ concentration ([Ca2+]i) that apparently contributes to cell death. This effect consists of several temporally and kinetically distinct phases. The initial elevation arises from release of Ca2+(i) stores; the second phase results from entry of Ca2+(e). In these experiments, we tested the hypothesis that release of mitochondrial Ca2+ through the mitochondrial permeability transition pore (MTP) contributes to the initial release of Ca2+(i). Neonatal rat cerebellar granule cells in culture and single cell microfluorimetry were used to examine MeHg-induced changes in [Ca2+]i and mitochondrial membrane potential (Psi(m)). Pretreatment with the MTP inhibitor cyclosporin A (CsA, 5 microM) delayed the initial phase of increased [Ca2+]i induced by 0.2 and 0.5 microM MeHg, but not 1.0 microM MeHg. CsA (5 microM) also delayed the irreversible loss of Psi(m) induced by 0.5 microM MeHg. Ca2+(e) was not required for either effect, because the effect of CsA on the first phase increase in [Ca2+]i and loss of Psi(m) was not altered in nominally Ca2+-free buffer. Increasing concentrations of MeHg (0.2-2.0 microM) caused increasing incidence of cell death at 24 h postexposure. Treatment with CsA provided protection against cytotoxicity at lower MeHg concentrations (0.2-0.5 microM), but not at higher MeHg concentrations (1.0-2.0 microM). Thus, the MTP appears to play a significant role in the cellular effects following acute exposure of cerebellar granule neurons to MeHg.