Tahmina Mujtaba

Enrichment of neurons and neural precursors from human embryonic stem cells.

Human embryonic stem (hES) cells proliferate and maintain their pluripotency for over a year in vitro (M. Amit, M. K. Carpenter, M. S. Inokuma, C. P. Chiu, C. P., Harris, M. A. Waknitz, J. Itskovitz-Eldor, and J. A. Thomson. 2000. Dev. Biol. 227: 271-278) and may therefore provide a cell source for cell therapies. hES cells were maintained for over 6 months in vitro (over 100 population doublings) before their ability to differentiate into the neural lineage was evaluated. Differentiation was induced by the formation of embryoid bodies that were subsequently plated onto appropriate substrates in defined medium containing mitogens. These populations contained cells that showed positive immunoreactivity to nestin, polysialylated neural cell adhesion molecule (PS-NCAM) and A2B5. After further maturation, these cells expressed additional neuron-specific antigens (such as MAP-2, synaptophysin, and various neurotransmitters). Calcium imaging demonstrated that these cells responded to neurotransmitter application. Electrophysiological analyses showed that cell membranes contained voltage-dependent channels and that action potentials were triggered by current injection. PS-NCAM and A2B5 immunoselection or culture conditions could be used to produce enriched populations (60-90%) which could be further differentiated into mature neurons. The properties of the hES-derived progenitors and neurons were found to be similar to those of cells derived from primary tissue. These data indicate that hES cells could provide a cell source for the neural progenitor cells and mature neurons for therapeutic and toxicological uses.

Isolation of Lineage-Restricted Neuronal Precursors from Multipotent Neuroepithelial Stem Cells

We have identified a neuronal-restricted precursor (NRP) cell that expresses E-NCAM (high polysialic-acid NCAM) and is morphologically distinct from multipotent neuroepithelial (NEP) cells (Kalyani et al., 1997) and spinal glial progenitors (Rao and Mayer-Proschel, 1997). NRP cells self renew over multiple passages in the presence of fibroblast growth factor (FGF) and neurotrophin-3 (NT-3) and differentiate in the presence of retinoic acid and the absence of FGF into postmitotic neurons. NRP cells can also be generated from multipotent E10.5 NEP cells. Clonal analysis shows that NRP cells arise from a NEP progenitor that generates other restricted CNS precursors. The NEP-derived NRPs undergo self renewal and can differentiate into multiple neuronal phenotypes. Thus, a direct lineal relationship exists between multipotential NEP cells and more restricted neuronal precursor cells present in vivo at E13.5 in the spinal cord.

Common neural progenitor for the CNS and PNS

Cultured spinal cord neuroepithelial (NEP) cells can differentiate into neurons, oligodendrocytes and astrocytes and are morphologically and antigenically distinct from neural crest stem cells (NCSCs) that generate the PNS. NEP cells, however, can generate p75/nestin-immunoreactive cells that are morphologically and antigenically similar to previously characterized NCSCs. NEP-derived p75-immunoreactive cells differentiate into peripheral neurons, smooth muscle, and Schwann cells in mass and clonal culture. Clonal analysis of NEP cells demonstrates that a common NEP progenitor cell generated both CNS and PNS phenotypes. Differentiation into NCSCs was promoted by BMP-2/4 and differentiation did not require cells to divide, indicating that BMP played an instructive role in the differentiation process. Thus, individual NEP cells are multipotent and can differentiate into most major types of cell in the CNS and PNS and that PNS differentiation involves a transition from a NEP stem to another more limited, p75-immunoreactive, neural crest stem cell.

Grafted lineage-restricted precursors differentiate exclusively into neurons in the adult spinal cord.

Multipotent neural stem cells (NSCs) have the potential to differentiate into neuronal and glial cells and are therefore candidates for cell replacement after CNS injury. Their phenotypic fate in vivo is dependent on the engraftment site, suggesting that the environment exerts differential effects on neuronal and glial lineages. In particular, when grafted into the adult spinal cord, NSCs are restricted to the glial lineage, indicating that the host spinal cord environment is not permissive for neuronal differentiation. To identify the stage at which neuronal differentiation is inhibited we examined the survival, differentiation, and integration of neuronal restricted precursor (NRP) cells, derived from the embryonic spinal cord of transgenic alkaline phosphatase rats, after transplantation into the adult spinal cord. We found that grafted NRP cells differentiate into mature neurons, survive for at least 1 month, appear to integrate within the host spinal cord, and extend processes in both the gray and white matter. Conversely, grafted glial restricted precursor cells did not differentiate into neurons. We did not observe glial differentiation from the grafted NRP cells, indicating that they retained their neuronal restricted properties in vivo. We conclude that the adult nonneurogenic CNS environment does not support the transition of multipotential NSCs to the neuronal commitment stage, but does allow the survival, maturation, and integration of NRP cells.

Expression of EGF receptor and FGF receptor isoforms during neuroepithelial stem cell differentiation.

To characterize the role of epidermal growth factor (EGF) and fibroblast growth factor (FGF) in regulating neuroepithelial stem cells differentiation, we have examined the expression of FGF, EGF, and their receptors by neuroepithelial (NEP) cells and their derivatives. Our results indicate that undifferentiated NEP cells express a subset of FGF receptor (FGFR) isoforms, but do not express platelet-derived growth factor receptors (PDGFRs) or epidermal growth factor receptor (EGFR). The FGFR pattern of expression by differentiated neuron and glial cells differs from that found on NEP stem cells. FGFR-4 is uniquely expressed on NEP cells, while FGFR-1 is expressed by both NEP cells and neurons, and FGFR-2 is down-regulated during neuronal differentiation. FGFRs present on astrocytes and oligodendrocytes also represent a subset of those present on NEP cells. Expression of FGF and EGF by NEP cells and their progeny was also examined. NEP cells synthesize detectable levels of both FGF-1 and FGF-2, and EGF. FGF-1 and FGF-2 synthesis is likely to be biologically relevant, as cells grown at high density do not require exogenous FGF for their survival and cells grown in the presence of neutralizing antibodies to FGF show a reduction in cell survival and division. Thus, neuroepithelial cells synthesize and respond to FGF, but not to EGF, and are therefore distinct from other neural stem cells (neurospheres). The unique pattern of expression of FGF isoforms may serve to distinguish NEP cells from their more differentiated progeny.

Characterization of the AMPA‐Activated Receptors Present on Motoneurons

Abstract: Motoneurons have been shown to be particularly sensitive to Ca2+‐dependent glutamate excitotoxicity, mediated via AMPA receptors (AMPARs). To determine the molecular basis for this susceptibility we have used immunocytochemistry, RT‐PCR, and electrophysiology to profile AMPARs on embryonic day 14.5 rat motoneurons. Motoneurons show detectable AMPAR‐mediated calcium permeability in vitro and in vivo as determined by cobalt uptake and electrophysiology. Motoneurons express all four AMPAR subunit mRNAs, with glutamate receptor (GluR) 2 being the most abundant (63.9 ± 4.8%). GluR2 is present almost exclusively in the edited form, and electrophysiology confirms that most AMPARs present are calcium‐impermeant. However, the kainate current in motoneurons was blocked an average of 32.0% by Joro spider toxin, indicating that a subset of the AMPARs is Ca2+‐permeable. Therefore, heterogeneity of AMPARs, rather than the absence of GluR2 or the presence of unedited GluR2, explains AMPAR‐mediated Ca2+ permeability. The relative levels of flip/flop isoforms of each subunit were also examined by semiquantitative PCR. Both isoforms were present, but the relative proportion varied for each subunit, and the flip isoform predominated. Thus, our data show that despite high levels of edited GluR2 mRNA, some AMPARs are Ca2+‐permeable, and this subset of AMPARs can account for the AMPAR‐mediated Ca2+ inflow inferred from cobalt uptake and electrophysiology studies.

Stable Expression of the Alkaline Phosphatase Marker Gene by Neural Cells in Culture and after Transplantation into the CNS Using Cells Derived from a Transgenic Rat

Multipotent stem cells and more developmentally restricted precursors have previously been isolated from the developing nervous system and their properties analyzed by culture assays in vitro and by transplantation in vivo. However, the variety of labeling techniques that have been used to identify grafted cells in vivo have been unsatisfactory. In this article we describe the characteristics of cells isolated from a transgenic rat in which the marker gene human placental alkaline phosphatase (hPAP) is linked to the ubiquitously active R26 gene promoter. We show that hPAP is readily detected in embryonic neuroepithelial stem cells, neuronal-restricted precursor cells, and glial-restricted precursor cells. Transgene expression is robust and can be detected by both immunocytochemistry and histochemistry. Furthermore, the levels of hPAP on the cell surface are sufficient for live cell labeling and fluorescence-activated cell sorting. Expression of hPAP is stable in isolated cells in culture and in cells transplanted into the spinal cord for at least 1 month. We submit that cells isolated from this transgenic rat will be valuable for studies of neural development and regeneration.

Isolation of a glial-restricted tripotential cell line from embryonic spinal cord cultures

Neuroepithelial stem cells (NEPs), glial‐restricted precursors (GRPs), and neuron‐restricted precursors (NRPs) are present during early differentiation of the spinal cord and can be identified by cell surface markers. In this article, we describe the properties of GRP cells that have been immortalized using a regulatable v‐myc retrovirus construct. Immortalized GRP cells can be maintained in an undifferentiated dividing state for long periods and can be induced to differentiate into two types of astrocytes and into oligodendrocytes in culture. A clonal cell line prepared from immortalized GRP cells, termed GRIP‐1, was also shown to retain the properties of a glial‐restricted tripotential precursor. Transplantation of green fluorescent protein (GFP)‐labeled subclones of the immortalized cells into the adult CNS demonstrates that this cell line can also participate in the in vivo development of astrocytes and oligodendrocytes. Late passages of the immortalized cells undergo limited transdifferentiation into neurons as assessed by expression of multiple neuronal markers. The availability of a conditionally immortalized cell line obviates the difficulties of obtaining a large and homogeneous population of GRPs that can be used for studying the mechanism and signals for glial cell differentiation as well as their application in transplantation protocols. GLIA 38:65–79, 2002.