Characterization of a multipotent neural progenitor cell line cloned from an adult p53-/- mouse cerebellum

Neurotoxicity screening in a multipotent neural stem cell line established from the mouse brain

Neural stem cells (NSCs) have mainly been applied to neurodegeneration in some medically intractable neurologic diseases. In this study, we established a novel NSC line and investigated the cytotoxic responses of NSCs to exogenous neurotoxicants, glutamates and reactive oxygen species (ROS). A multipotent NSC line, B2A1 cells, was established from long-term primary cultures of oligodendrocyte-enriched cells from an adult BALB/c mouse brain. B2A1 cells could be differentiated into neuronal, astrocytic and oligodendroglial lineages. The cells also expressed genotypic mRNA messages for both neural progenitor cells and differentiated neuronoglial cells. B2A1 cells treated with hydrogen peroxide and L-buthionine-(S,R)-sulfoximine underwent 30-40% cell death, while B2A1 cells treated with glutamate and kainate showed 25-35% cell death. Cytopathologic changes consisting of swollen cell bodies, loss of cytoplasmic processes, and nuclear chromatin disintegration, developed after exposure to both ROS and excitotoxic chemicals. These results suggest that B2A1 cells may be useful in the study of NSC biology and may constitute an effective neurotoxicity screening system for ROS and excitotoxic chemicals.

Molecular characterization of mitocalcin, a novel mitochondrial Ca2+-binding protein with EF-hand and coiled-coil domains

Here we have identified and characterized a novel mitochondrial Ca2+-binding protein, mitocalcin. Western blot analysis demonstrated that mitocalcin was widely expressed in mouse tissues. The expression in brain was increased during post-natal to adult development. Further analyses were carried out in newly established neural cell lines. The protein was expressed specifically in neurons but not in glial cells. Double-labeling studies revealed that mitocalcin was colocalized with mitochondria in neurons differentiated from 2Y-3t cells. In addition, mitocalcin was enriched in the mitochondrial fraction purified from the cells. Immunohistochemical studies on mouse cerebellum revealed that the expression pattern of mitocalcin in glomeruli of the internal granular and molecular layers was well overlapped by the distribution pattern of mitochondria. Immunogold electron microscopy showed that mitocalcin was associated with mitochondrial inner membrane. Overexpression of mitocalcin in 2Y-3t cells resulted in neurite extension. Inhibition of the expression in 2Y-3t cells caused suppression of neurite outgrowth and then cell death. These findings suggest that mitocalcin may play roles in neuronal differentiation and function through the control of mitochondrial function.

Multipotency of FBD-103a, a neural progenitor cell line from the p53-deficient mouse

We previously established cell lines from brains of p53-deficient embryos, and have now characterized one of these lines, FBD-103a, in detail. Recloning FBD-103a yielded 3 types of subclones: 5 generated the neuronal lineage (Type 1), 3 generated the glial lineage (Type 2), and 10 gave rise to both lineages as the parental line (Type 3), indicating that FBD-103a is a multipotent neural progenitor cell line indistinguishable from true neural stem cells. RT-PCR analyses of transcription factor expression indicated that the transition of multipotent Type 3 clones to either neuronally or glially differentiated progeny was marked by down-regulation of Ascl1/Mash1 and Olig1 and up-regulation of Nrsf/Rest. As expected for neural stem cells, FBD-103a and Type 3 clones formed neurospheres when cultured on a non-adhesive substrate in a serum-free medium containing fibroblast growth factor-2 (FGF2). Interestingly, the transition between Type 3 and Type 1 neuronal- or Type 2 glial-specified cells proved to be reversible; Type 1 and Type 2 subclones could also form neurospheres, from which both neuron-generating and glia-generating progenies could be derived. Moreover, when maintained on an adherent substratum that prevented neurosphere formation, but with FGF2 and without serum, Type 2 clones could generate Type 3 multipotent cells. Thus, at least in the absence of p53, specialized cell-cell interactions within neurospheres are not essential for persistence or recapture of the capacity for self-renewal and multipotency by cells differentiating along glial pathways, a result of possible significance to the pathogenesis of malignant brain tumors.

An attempt to generate neurons from an astrocyte progenitor cell line FBD-104

In the present study, a clonal astrocyte progenitor cell line derived from p53-deficient fetal brains, named FBD-104, was characterized in monolayer and suspension culture. In monolayer culture with medium containing 10% serum, FBD-104 cells expressed some markers of astrocytes, such as glial fibrillary acidic protein (GFAP), S100beta, and glutamate aspartate transporter (GLAST). They never expressed any markers of neurons or oligodendrocytes. Thus the cell line appears to be restricted to the astroglial lineage. However, in suspension culture in serum-free medium supplemented with EGF and FGF2, FBD-104 cells proliferated and formed neurospheres expressing mRNAs for Mash1 and Math3, generating cells expressing neuron specific beta-III tubulin. Re-plating the spheres onto an adhesive substrate and withdrawal of the growth factors induced the expression of mRNAs for NeuroD and Olig2 and generated more beta-III tubulin-positive cells. The present study demonstrated that neurosphere culture is an efficient method to induce neurogenesis from the astrocyte progenitor cell line FBD-104. We also determined that pretreatment with FGF2 caused a significant increase in yield of neurospheres. Thus, the FBD-104 line is an interesting in vitro model to study effect of trophic factors and adhesive substrates on lineage determination of neural progenitor cells.

A bipotent neural progenitor cell line cloned from a cerebellum of an adultp53-deficient mouse generates both neurons and oligodendrocytes

Here we report developmental characteristics of a clonal cell line 2Y-3t established from a multifocal neoplasm that arose in a cerebellum of an adult p53-deficient mouse. The tumorigenicity of the line was not observed in soft agar assay or in nude mouse assay. In serum-containing medium, 2Y-3t cells were epithelial-like in morphology and were mitotic. When they were cultured in serum-free medium, the expressions of neural stem and/or progenitor cell markers were decreased. Concomitantly, the expressions of neuronal and oligodendrocyte markers were increased in concert with morphological differentiation, and DNA synthesis ceased. None of astrocyte markers were detected under these culture conditions. Double-labelling studies revealed that two cell populations coexisted, expressing neuronal or oligodendrocyte markers. Triiodothyronine (T3) increased the oligodendrocyte population when 2Y-3t cells were cultured in serum-free medium. Recloning of the line gave rise to three types of subclones. Sixteen subclones were capable of generating both neurons and oligodendrocytes, four subclones were capable of generating only neurons and one subclone was capable of generating only oligodendrocytes. Thus, 2Y-3t cells have characteristics of bipotent neural progenitor cells capable of generating both neurons and oligodendrocytes. In addition, the line expressed mRNA for Pax-2 and had GAD67-positive cells when cultured in serum-free medium. However, none of the mRNAs for Zic-1, Math1, zebrin or Calbindin-D28k were detected, suggesting that the 2Y-3t line might generate the GABAergic interneuron lineage of the mouse cerebellum.