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We have previously identified multipotent neuroepithelial (NEP) stem cells and lineage-restricted,self-renewing precursor cells termed NRPs (neuron-restricted precursors) and GRPs (glial-restricted precursors) present in the developing rat spinal cord (A. Kalyani,K. Hobson,and M. S. Rao,1997,Dev. Biol. 186,202-223; M. S. Rao and M. Mayer-Proschel,1997,Dev. Biol. 188,48-63; M. Mayer-Proschel,A. J. Kalyani,T. Mujtaba,and M. S. Rao,1997,Neuron 19,773-785). We now show that cells identical to rat NEPs,NRPs,and GRPs are present in mouse neural tubes and that immunoselection against cell surface markers E-NCAM and A2B5 can be used to isolate NRPs and GRPs,respectively. Restricted precursors similar to NRPs and GRPs can also be isolated from mouse embryonic stem cells (ES cells). ES cell-derived NRPs are E-NCAM immunoreactive,undergo self-renewal in defined medium,and differentiate into multiple neuronal phenotypes in mass culture. ES cells also generate A2B5-immunoreactive cells that are similar to E9 NEP-cell-derived GRPs and can differentiate into oligodendrocytes and astrocytes. Thus,lineage restricted precursors can be generated in vitro from cultured ES cells and these restricted precursors resemble those derived from mouse neural tubes. These results demonstrate the utility of using ES cells as a source of late embryonic precursor cells. View Publication

The neurosphere assay can detect and expand neural stem cells (NSCs) and progenitor cells,but it cannot discriminate between these two populations. Given two assays have purported to overcome this shortfall,we performed a comparative analysis of the distribution and frequency of NSCs and progenitor cells detected in 400 mum coronal segments along the ventricular neuraxis of the adult mouse brain using the neurosphere assay,the neural colony forming cell assay (N-CFCA),and label-retaining cell (LRC) approach. We observed a large variation in the number of progenitor/stem cells detected in serial sections along the neuraxis,with the number of neurosphere-forming cells detected in individual 400 mum sections varying from a minimum of eight to a maximum of 891 depending upon the rostral-caudal coordinate assayed. Moreover,the greatest variability occurred in the rostral portion of the lateral ventricles,thereby explaining the large variation in neurosphere frequency previously reported. Whereas the overall number of neurospheres (3730 +/- 276) or colonies (4275 +/- 124) we detected along the neuraxis did not differ significantly,LRC numbers were significantly reduced (1186 +/- 188,7 month chase) in comparison to both total colonies and neurospheres. Moreover,approximately two orders of magnitude fewer NSC-derived colonies (50 +/- 10) were detected using the N-CFCA as compared to LRCs. Given only 5% of the LRCs are cycling (BrdU+/Ki-67+) or competent to divide (BrdU+/Mcm-2+),and proliferate upon transfer to culture,it is unclear whether this technique selectively detects endogenous NSCs. Overall,caution should be taken with the interpretation and employment of all these techniques. View Publication

BAG-1 protein has been well characterized as necessary for proper neuronal development. However,little is known about the function of BAG-1 in the adult brain. In this work,the expression and localization of BAG-1 in the mature mouse brain was studied. The levels of both BAG-1 isoforms decrease significantly in the brain during development. BAG-1 was found preferentially expressed in Neuronal Precursor Cells (NPCs) in the two major niches of neurogenesis. Lentiviral mediated overexpression of BAG-1 increased the proliferation rate of cultured NPCs. In addition,depletion of BAG-1 from NPCs induced a decrease in NPCs proliferation in the presence of a stress hormone,corticosterone. These data suggest a role for BAG-1 in mechanisms of neurogenesis in the adult mouse brain. View Publication

Since the discovery of neural stem cells (NSC) in the embryonic and adult mammalian central nervous system (CNS),there have been a growing numbers of tissue culture media and protocols to study and functionally characterize NSCs and its progeny in vitro. One of these culture systems introduced in 1992 is referred to as the Neurosphere Assay,and it has been widely used to isolate,expand,differentiate and even quantify NSC populations. Several years later because its application as a quantitative in vitro assay for measuring NSC frequency was limited,a new single-step semisolid based assay,the Neural Colony Forming Cell (NCFC) assay was developed to accurately measure NSC numbers. The NCFC assay allows the discrimination between NSCs and progenitors by the size of colonies they produce (i.e.,their proliferative potential). The evolution and continued improvements made to these tissue culture tools will facilitate further advances in the promising application of NSCs for therapeutic use. View Publication

Regeneration of insulin-producing β-cells from resident pancreas progenitors requires an understanding of both progenitor identity and lineage plasticity. One model suggested that a rare β-cell sub-population within islets demonstrated multi-lineage plasticity. We hypothesized that β-cells from young mice (postnatal day 7,P7) exhibit such plasticity and used a model of islet dedifferentiation toward a ductal epithelial-cell phenotype to test this theory. RIPCre;Z/AP(+/+) mice were used to lineage trace the fate of β-cells during dedifferentiation culture by a human placental alkaline phosphatase (HPAP) reporter. There was a significant loss of HPAP-expressing β-cells in culture,but remaining HPAP(+) cells lost insulin expression while gaining expression of the epithelial duct cell marker cytokeratin-19 (Ck19). Flow cytometry and recovery of β-cell subpopulations from whole pancreas vs. islets suggest that the HPAP(+)Ck19(+) cells had derived from insulin-positive,glucose-transporter-2-low (Ins(+)Glut2(LO)) cells,representing 3.5% of all insulin-expressing cells. The majority of these cells were found outside of islets within clusters of <5 β-cells. These insulin(+)Glut2(LO) cells demonstrated a greater proliferation rate in vivo and in vitro as compared to insulin(+)Glut2(+) cells at P7,were retained into adulthood,and a subset differentiated into endocrine,ductal,and neural lineages,illustrating substantial plasticity. Results were confirmed using RIPCre;ROSA- eYFP mice. Quantitative PCR data indicated these cells possess an immature β-cell phenotype. These Ins(+)Glut2(LO) cells may represent a resident population of cells capable of forming new,functional β-cells,and which may be potentially exploited for regenerative therapies in the future. View Publication

Development of therapeutics for genetically complex neurodegenerative diseases such as sporadic amyotrophic lateral sclerosis (ALS) has largely been hampered by lack of relevant disease models. Reprogramming of sporadic ALS patients' fibroblasts into induced pluripotent stem cells (iPSC) and differentiation into affected neurons that show a disease phenotype could provide a cellular model for disease mechanism studies and drug discovery. Here we report the reprogramming to pluripotency of fibroblasts from a large cohort of healthy controls and ALS patients and their differentiation into motor neurons. We demonstrate that motor neurons derived from three sALS patients show de novo TDP-43 aggregation and that the aggregates recapitulate pathology in postmortem tissue from one of the same patients from which the iPSC were derived. We configured a high-content chemical screen using the TDP-43 aggregate endpoint both in lower motor neurons and upper motor neuron like cells and identified FDA-approved small molecule modulators including Digoxin demonstrating the feasibility of patient-derived iPSC-based disease modeling for drug screening. View Publication

The genetic reprogramming technology allows one to generate pluripotent stem cells for individual patients. These cells,called induced pluripotent stem cells (iPSCs),can be an unlimited source of specialized cell types for the body. Thus,autologous somatic cell replacement therapy becomes possible,as well as the generation of in vitro cell models for studying the mechanisms of disease pathogenesis and drug discovery. Amyotrophic lateral sclerosis (ALS) is an incurable neurodegenerative disorder that leads to a loss of upper and lower motor neurons. About 10% of cases are genetically inherited,and the most common familial form of ALS is associated with mutations in the SOD1 gene. We used the reprogramming technology to generate induced pluripotent stem cells with patients with familial ALS. Patient-specific iPS cells were obtained by both integration and transgene-free delivery methods of reprogramming transcription factors. These iPS cells have the properties of pluripotent cells and are capable of direct differentiation into motor neurons. View Publication