Transgenic enrichment of mouse embryonic stem cell-derived progenitor motor neurons.

Embryonic stem cells (ESCs) hold great potential for replacing neurons following injury or disease. The therapeutic and diagnostic potential of ESCs may be hindered by heterogeneity in ESC-derived populations. Drug selection has been used to purify ESC-derived cardiomyocytes and endothelial cells but has not been applied to specific neural lineages. In this study we investigated positive selection of progenitor motor neurons (pMNs) through transgenic expression of the puromycin resistance enzyme, puromycin N-acetyl-transferase (PAC), under the Olig2 promoter. The protein-coding region in one allele of Olig2 was replaced with PAC to generate the P-Olig2 cell line. This cell line provided specific puromycin resistance in cells that express Olig2, while Olig2(-) cells were killed by puromycin. Positive selection significantly enriched populations of Olig2(+) pMNs. Committed motoneurons (MNs) expressing Hb9, a common progeny of pMNs, were also enriched by the end of the selection period. Selected cells remained viable and differentiated into mature cholinergic MNs and oligodendrocyte precursor cells. Drug resistance may provide a scalable and inexpensive method for enriching desired neural cell types for use in research applications.

Ultraconserved elements in the Olig2 promoter.

BACKGROUND: Oligodendrocytes are specialized cells of the nervous system that produce the myelin sheaths surrounding the axons of neurons. Myelinating the axons increases the speed of nerve conduction and demyelination contributes to the pathology of neurodegenerative diseases such as multiple sclerosis. Oligodendrocyte differentiation is specified early in development by the expression of the basic-helix-loop-helix transcription factor Olig2 in the ventral region of the neural tube. Understanding how Olig2 expression is controlled is therefore essential for elucidating the mechanisms governing oligodendrocyte differentiation. A method is needed to identify potential regulatory sequences in the long stretches of adjacent non-coding DNA that flank Olig2. METHODOLOGY/PRINCIPAL FINDINGS: We identified ten potential regulatory regions upstream of Olig2 based on a combination of bioinformatics metrics that included evolutionary conservation across multiple vertebrate genomes, the presence of potential transcription factor binding sites and the existence of ultraconserved elements. One of our computational predictions includes a region previously identified as the Olig2 basal promoter, suggesting that our criterion represented characteristics of known regulatory regions. In this study, we tested one candidate regulatory region for its ability to modulate the Olig2 basal promoter and found that it represses expression in undifferentiated embryonic stem cells. CONCLUSIONS/SIGNIFICANCE: The regulatory region we identified modifies the expression regulated by the Olig2 basal promoter in a manner consistent with our current understanding of Olig2 expression during oligodendrocyte differentiation. Our results support a model in which constitutive activation of Olig2 by its basal promoter is repressed in undifferentiated cells by upstream repressive elements until that repression is relieved during differentiation. We conclude that the potential regulatory elements presented in this study provide a good starting point for unraveling the cis-regulatory logic that governs Olig2 expression. Future studies of the functionality of the potential regulatory elements we present will help reveal the interactions that govern Olig2 expression during development.

Embryonic stem cells as a platform for analyzing neural gene transcription.

There is a need for improved methods to analyze transcriptional control of mammalian stem cell genes. We propose that embryonic stem cells (ESCs) will have broad utility as a model system, because they can be manipulated genetically and then differentiated into many cell types in vitro, avoiding the need to make mice. Results are presented demonstrating the utility of ESCs for analyzing cis-acting sequences using Olig2 as a model gene. Olig2 is a transcription factor that plays a key role in the development of a ventral compartment of the nervous system and the oligodendrocyte lineage. The functional role of an upstream region (USR) of the Olig2 gene was investigated in ESCs engineered at the undifferentiated stage and then differentiated into ventral neural cells with sonic hedgehog and retinoic acid. Deletion of the USR from the native gene via gene targeting eliminates expression in ventral neural cells differentiated in cell culture. The USR is also essential for regulated expression of an Olig2 transgene inserted at a defined foreign chromosomal site. A subregion of the USR has nonspecific promoter activity in transient transfection assays in cells that do not express Olig2. Taken together, the data demonstrate that the USR contains a promoter for the Olig2 gene and suggest that repression contributes to specific expression. The technology used in this study can be applied to a wide range of genes and cell types and will facilitate research on cis-acting DNA elements of mammalian genes.

The effects of soluble growth factors on embryonic stem cell differentiation inside of fibrin scaffolds.

The goal of this research was to determine the effects of different growth factors on the survival and differentiation of murine embryonic stem cell-derived neural progenitor cells (ESNPCs) seeded inside of fibrin scaffolds. Embryoid bodies were cultured for 8 days in suspension, retinoic acid was applied for the final 4 days to induce ESNPC formation, and then the EBs were seeded inside of three-dimensional fibrin scaffolds. Scaffolds were cultured in the presence of media containing different doses of the following growth factors: neurotrophin-3 (NT-3), basic fibroblast growth factor (bFGF), platelet-derived growth factor (PDGF)-AA, ciliary neurotrophic factor, and sonic hedgehog (Shh). The cell phenotypes were characterized using fluorescence-activated cell sorting and immunohistochemistry after 14 days of culture. Cell viability was also assessed at this time point. Shh (10 ng/ml) and NT-3 (25 ng/ml) produced the largest fractions of neurons and oligodendrocytes, whereas PDGF (2 and 10 ng/ml) and bFGF (10 ng/ml) produced an increase in cell viability after 14 days of culture. Combinations of growth factors were tested based on the results of the individual growth factor studies to determine their effect on cell differentiation. The incorporation of ESNPCs and growth factors into fibrin scaffolds may serve as potential treatment for spinal cord injury.

Optimization of fibrin scaffolds for differentiation of murine embryonic stem cells into neural lineage cells.

The objective of this research was to determine the appropriate cell culture conditions for embryonic stem (ES) cell proliferation and differentiation in fibrin scaffolds by examining cell seeding density, location, and the optimal concentrations of fibrinogen, thrombin, and aprotinin (protease inhibitor). Mouse ES cells were induced to become neural progenitors by adding retinoic acid for 4 days to embryoid body (EB) cultures. For dissociated EBs, the optimal cell seeding density and location was determined to be 250,000 cells/cm(2) seeded on top of fibrin scaffolds. For intact EBs, three-dimensional (3D) cultures with one EB per 400 microL fibrin scaffold resulted in greater cell proliferation and differentiation than two-dimensional (2D) cultures. Optimal concentrations for scaffold polymerization were 10mg/mL of fibrinogen and 2 NIH units/mL of thrombin. The optimal aprotinin concentration was determined to be 50 microg/mL for dissociated EBs (2D) and 5 microg/mL for intact EBs in 3D fibrin scaffolds. Additionally, after 14 days in 3D culture EBs differentiated into neurons and astrocytes as indicated by immunohistochemisty. These conditions provide an optimal fibrin scaffold for evaluating ES cell differentiation and proliferation in culture, and for use as a platform for neural tissue engineering applications, such as the treatment for spinal cord injury.

Multi-germ layer lineage central nervous system repair: nerve and vascular cell generation by embryonic stem cells transplanted in the injured brain.

OBJECT: To restore proper function to a damaged central nervous system (CNS) through transplantation, it is necessary to replace both neural and nonneural elements that arise from different germ layers in the embryo. Mounting evidence indicates the importance of signals related to vasculogenesis in governing neural proliferation and differentiation in early CNS development. Here, the authors examined whether embryonic stem cell (ESC)-derived progenitors can selectively generate both neural and endothelial cells after transplantation in the damaged CNS. METHODS: Injections of 20 nmol N-methyl-D-aspartate created a unilateral striatal injury in 7-day-old rats. One week postinjury, murine ESCs, neural-induced with retinoic acid, were transplanted into the injured striatum. Histological staining, laser confocal microscopy, and transmission electron microscopy of grafted ESCs were performed 1 week posttransplantation. CONCLUSIONS: Transplanted ESCs differentiated into neural cells, which segregated into multiple pools and formed neurons that conformed to host cytoarchitecture. The ESCs also generated endothelial cells, which integrated with host cells to form chimeric vasculature. The combination of ESC pluripotentiality and multiple germ layer differentiation provides a new conceptual framework for CNS repair.

Transplantation of embryonic stem cells overexpressing Bcl-2 promotes functional recovery after transient cerebral ischemia.

The study tested the hypothesis that transplantation of embryonic stem (ES) cells into rat cortex after a severe focal ischemia would promote structural repair and functional recovery. Overexpression of the human anti-apoptotic gene bcl-2 in ES cells was tested for increasing survival and differentiation of transplanted cells and promoting functional benefits. Mouse ES cells, pretreated with retinoic acid to induce differentiation down neural lineages, were transplanted into the post-infarct brain cavity of adult rats 7 days after 2-h occlusion of the middle cerebral artery (MCA). Over 1-8 weeks after transplantation, the lesion cavity filled with ES cell-derived cells that expressed markers for neurons, astrocytes, oligodendrocytes, and endothelial cells. ES cell-derived neurons exhibited dendrite outgrowth and formed a neuropil. ES cell-transplanted animals exhibited enhanced functional recovery on neurological and behavioral tests, compared to control animals injected with adult mouse cortical cells or vehicle. Furthermore, transplantation with ES cells overexpressing Bcl-2 further increased the survival of transplanted ES cells, neuronal differentiation, and functional outcome. This study supports that ES cell transplantation and gene modification may have values for enhancing recovery after stroke.

Promoter analysis in ES cell-derived neural cells.

Neural cells derived from ES cells in cell culture (ESNCs) have many of the properties of normal neural cells and provide a model of "neurogenesis-in-a-dish." Here we show that ESNCs provide a powerful system for analyzing neural gene transcription. ES cells are transfected with bacterial artificial chromosomes (BACs) containing Olig2, a gene with a key role in neural fate choice. One BAC is modified by recombineering to insert a reporter gene and a gene for selecting stably transfected clones. Another BAC contains a deletion of a suspected Olig2 promoter. Stable transgenic clones of ES cells are isolated, differentiated in culture, and the expression of transgenes is assayed. Differentiated cells dramatically up-regulate transgene expression and a deletion analysis reveals a basal promoter for Olig2. The combination of ESNCs and BAC recombineering will have broad application for analyzing gene transcription in the nervous system and will be applicable to human ES cells. The general approach should also be applicable to the many other cell lineages that can now be derived from mouse and human ES cells in culture.

Neurotrophin and GDNF family ligands promote survival and alter excitotoxic vulnerability of neurons derived from murine embryonic stem cells.

Embryonic stem (ES) cells are genetically manipulable pluripotential cells that can be differentiated in vitro into neurons, oligodendrocytes, and astrocytes. Given their potential utility as a source of replacement cells for the injured nervous system and the likelihood that transplantation interventions might include co-application of growth factors, we examined the effects of neurotrophin and GDNF family ligands on the survival and excitotoxic vulnerability of ES cell-derived neurons (ES neurons) grown in vitro. ES cells were differentiated down a neural lineage in vitro using the 4-/4+ protocol (Bain et al., Dev Biol 168:342-57, 1995). RT-PCR demonstrated expression of receptors for neurotrophins and GDNF family ligands in ES neural lineage cells. Neuronal expression of GFRalpha1, GFRalpha2, and ret was confirmed by immunocytochemistry. Exposure to 30-100 ng/ml GDNF or neurturin (NRTN) resulted in activation of ret. Addition of NT-3 and GDNF did not increase cell division but did increase the number of neurons in the cultures 7 days after plating. Pretreatment with NT-3 enhanced the vulnerability of ES neurons to NMDA-induced death (100 microM NMDA for 10 min) and enhanced the NMDA-induced increase in neuronal [Ca2+]i, but did not alter expression of NMDA receptor subunits NR2A or NR2B. In contrast, pretreatment with GDNF reduced the vulnerability of ES neurons to NMDA-induced death while modestly enhancing the NMDA-induced increase in neuronal [Ca2+]i. These findings demonstrate that the response of ES-derived neurons to neurotrophins and GDNF family ligands is largely similar to that of other cultured central neurons.

Dividing Olig2-expressing progenitor cells derived from ES cells.

G-Olig2 is a knock-in ES cell line with GFP inserted into the Olig2 gene so that ES cell-derived neural cells that express Olig2 also express GFP. This tool allows visualization of the subset of cells that differentiate along the Olig2-expressing pathway. By manipulating culture conditions, it is possible to induce Olig2 expression in rapidly dividing cells. These cells have many of the features of glial progenitor cells but, unlike other glial progenitors, are able to divide rapidly for at least 1 month while still expressing Olig2. Even after 1-month expansion, the cells differentiate readily into astrocyte-like and oligodendrocyte-like cells when switched to serum-containing medium. Cellular memory is the property whereby cells remain specified to a particular lineage or pathway while undergoing division. ES cell-derived neural cells show cellular memory for a glial progenitor phenotype and thus provide a new and tractable model for this basic feature of neural development.

Double lox targeting for neural cell transgenesis.

ES cells differentiated along the neural lineage in vitro are an attractive model system. Here we have developed ES cell lines that are suitable for inserting transgenes at a single chromosomal site. ES cell line CE1 (for Cassette Exchange) contains one "acceptor" module (CE1) that allows for efficient double lox targeting. The site is also permissive for gene expression in neural progenitor cells, as well as differentiated neurons and glia. Line CE2 was derived by swapping a puromycin resistance cassette into CE1. Neural progenitors derived from this line are puromycin-resistant. A beta-actin/GFP expression cassette was inserted into the CE1 site to create CE3. The CE3 cell line was differentiated into neural cells and displayed strong EGFP expression in neural progenitors, differentiated neurons and glia. Differentiated CE3 ES cells (4-/4+ RA) were transplanted into the injured rat somatosensory cortex where many of the transplanted cells survived and differentiated into neurons expressing GFP. This strategy for creating sets of transgenic lines with multiple cassettes inserted into a single chromosomal site provides a powerful tool for studying development and function of ES cell-derived neural cells. Many of these will be useful in transplantation research.

A subset of ES-cell-derived neural cells marked by gene targeting.

Embryonic stem cells differentiate efficiently in culture into neural progenitors, neurons, oligodendrocytes, and astrocytes. An embryonic stem (ES) cell line with green fluorescent protein (GFP) inserted into the gene for Olig2, a lineage-specific transcription factor, permits visualization and physical separation of a subset of living ES-cell-derived neural cells. GFP-expressing cells have morphological and antigenic properties of the oligodendrocyte lineage. The differentiation of living GFP-expressing cells can be followed in cultures, and they can be separated by fluorescence-activated cell sorting and cultured as pure populations. This system will allow detailed biochemical and molecular analysis of a neural differentiation pathway at a level not previously feasible. The strategy may have general applicability, since other neural lineages can be marked in an analogous manner.

Large-scale sources of neural stem cells.

Large-scale sources of neural stem cells are crucial for both basic research and novel approaches toward treating neurological disorders. Three sources that produce neural cells closely resembling their normal counterparts are now available: oncogene immortalized stem cells, neurospheres, and embryonic stem cell (ES)-derived neural cells. Cells including multiple subtypes of CNS and PNS neurons, as well as oligodendrocytes, Schwann cells, and astrocytes, are modeled by these large-scale sources. Although most cell lines were originally from rodents, their human counterparts are being discovered and characterized.