Markers of murine embryonic and neural stem cells, neurons and astrocytes: reference points for developmental neurotoxicity testing.

Developmental neurotoxicity (DNT) is a serious concern for environmental chemicals, as well as for food and drug constituents. Animal-based DNT models have relatively low sensitivity, and they are burdened by high work-load, cost and animal ethics. Murine embryonic stem cells (mESC) recapitulate several critical processes involved in the development of the nervous system if they are induced to differentiate into neural cells. They therefore represent an alternative toxicological model to predict human hazard. In this review, we discuss how mESC can be used for DNT assays. We have compiled a list of mRNA markers that define undifferentiated mESC (n = 42), neural stem cells (n = 73), astrocytes (n = 25) and the pattern of different neuronal and non-neuronal cell types generated (n = 57). We propose that transcriptional profiling can be used as a sensitive endpoint in toxicity assays to distinguish neural differentiation states during normal and disturbed development. Importantly, we believe that it can be scaled up to relatively high throughput whilst still providing rich information on disturbances affecting small cell subpopulations. Moreover, this approach can provide insight into underlying mechanisms and pathways of toxicity. We broadly discuss the methodological basis of marker lists and DNT assay design. The discussion is put in the context of a new generation of alternative assays (embryonic stem cell based DNT testing = ESDNT V2.0), that may later include human induced pluripotent stem cells, and that are not designed for 1:1 replacement of animal experiments, but are rather intended to improve human risk assessment by using independent scientific principles.

Efficient generation of neural precursors from adult human skin: astrocytes promote neurogenesis from skin-derived stem cells.

BACKGROUND: Neural stem cells are a potential source of cells for drug screening or cell-based treatments for neurodegenerative diseases. However, ethical and practical considerations limit the availability of neural stem cells derived from human embryonic tissue. An alternative source of human neural stem cells is needed; a source that is readily accessible, easily expanded, and reliably induced to a neural fate. METHODS: Dermis isolated from biopsy samples of adult human skin was cultured and expanded in the presence of the mitogens epidermal growth factor (EGF) and fibroblast growth factor 2 (FGF 2), and then by serum. We used immunocytochemical techniques, clonal analysis, and physiological characterisation to assess neural differentiation after the treatment of expanded cells with novel induction media. FINDINGS: Initial characterisation of skin samples confirmed the absence of nestin, a neural precursor marker. Sequential culture in EGF and FGF 2 followed by adherent expansion in serum, and re-exposure to mitogens in substrate-free conditions resulted in large numbers of nestin-positive/musashi-positive neural precursors. Subsequent exposure of these precursors to hippocampal-astrocyte-derived signals resulted in cells of neuronal morphology that had stable expression of markers of neuronal differentiation (neurofilament, beta tubulin). We also show the presence of voltage-dependent calcium transients, and demonstrate monoclonal neural potential. INTERPRETATION: We describe the isolation and characterisation of cells derived from adult human dermis that can be expanded for extended periods of time in vitro, while retaining inducible neural potential. The generation of almost limitless numbers of neural precursors from a readily accessible autologous adult human source provides a platform for further experimental studies and has potential therapeutic implications.

Localization of dopamine D1-receptor to A-type horizontal cells in the rabbit retina by single cell RT-PCR.

Dopamine is an important neurotransmitter regulating light-dark adaptation in the retina. The effect of dopamine is widespread and dependent on the localization of its receptors. We performed single cell RT-PCR on A-type horizontal cells visually selected from dissociated rabbit retinal neurons. Dopamine D1-receptor mRNA was positively identified. Subsequent sequencing of the fragment showed 82% homology with rat D1 receptor and 87% homology with human D1 receptor. This study supported previous observations that dopamine regulated A-type horizontal cell coupling via D1 receptors at the level of transcription.

Postnatal astrocytes promote neural induction from adult human bone marrow-derived stem cells.

Neural stem cells (NSCs) have generated considerable interest because of their potential as a source of defined cells for drug screening or cell-based therapies for neurodegenerative diseases. Ethical and practical considerations limit the availability of human fetal-derived neural tissue and highlight the need to consider alternative sources of human NSCs. Because of their ready availability, their ability to be easily expanded, and reports of neural potential, bone marrow-derived populations have become the focus of intense study with regard to their potential clinical utility. However, recent identification of spontaneous cell fusion and limited neuronal differentiation has tempered initial optimism. In this study, we demonstrate the monoclonal neural and mesodermal potential of adult human bone marrow mesenchymal cells. Critically, we show that sequential treatment with the mitogens epidermal growth factor (EGF) and fibroblast growth factor-2 (FGF-2) followed by postnatal hippocampal astrocyte conditioned medium significantly promotes the generation of neurofilament(+)/beta-tubulin(+) cells from bone marrow precursors. The ability to generate almost limitless numbers of neural precursors from a readily accessible autologous adult human source provides a platform for further studies and potentially has important therapeutic implications.