Functional analysis of embryonic stem cell-derived glial cells after integration into hippocampal slice cultures.

Embryonic stem (ES) cell-derived neural progenitor cells (ESNPs) generated in vitro are multipotent progenitors which can differentiate into oligodendrocytes, astrocytes, and neurons. Given the exciting prospects for ES cell-based treatments of neurological disorders, several studies investigated the migration, integration, and differentiation of grafted ESNPs into neurons and glial cells. However, little is known about the functional properties of transplanted ESNPs on the single cell level. In this study, we combined electrophysiology, single cell reverse transcription polymerase chain reaction (RT-PCR) and immunochemistry to determine the developmental time course of molecular and functional properties of ES cell-derived glial precursors (ESGPs) after deposition onto hippocampal slice cultures. Based on functional criteria, donor cells possessed three different phenotypes. During an observation period of 3 weeks after engraftment, the proportion of donor cells with a passive current pattern (type 3) continuously increased. The majority of these cells expressed astroglial markers. Type 3 host cells underwent similar developmental changes. In contrast, donor and host cells expressing time- and voltage-dependent currents (types 1, 2) displayed different developmental profiles. Importantly, type 2 donor and host cells also differed in the expression of inwardly rectifying K(+) channels. This suggests that despite several similarities in overall current phenotypes and timing of maturation, many donor cells integrated into host tissue but did not acquire the full set of ion channels present in their native counterparts. These findings emphasize the need to carefully characterize ES cell-derived progeny aimed for neural repair and cell-mediated gene transfer strategies.

Generation and potential biomedical applications of embryonic stem cell-derived glial precursors.

Recent progress in embryonic and adult stem cell research has opened new perspectives for generating large numbers of different neural cell types in vitro and using them for nervous system repair. Several lines of arguments suggest that myelin diseases represent particularly attractive targets for cell-based therapies. First, in contrast to neuronal cell replacement, a single and uniform cell type, the oligodendrocyte progenitor, suffices for therapeutic remyelination in all areas of the CNS, with no need for complex circuit integration. Second, there is an increasing understanding of the mechanisms regulating the recruitment of stem and progenitor cells into CNS lesions. Third, stem cells represent excellent vehicles for cell-mediated gene transfer, enabling novel approaches, which combine classic cell replacement with the delivery of therapeutic factors. Among the various donor sources, embryonic stem (ES) cells stand out as a population featuring pluripotency, unlimited self-renewal and amenability to gene targeting. Here we discuss the advantages, challenges and perspectives of bringing this unique cell type closer to a clinical application for treating myelin diseases and other neurological disorders.

Electrophysiological evaluation of engrafted stem cell-derived neurons.

Recent advances in the neural stem cell field have provided a wealth of methods for generating large amounts of purified neuronal precursor cells. It has become a question of paramount importance to determine whether these cells integrate and interact with established neural circuitry after engraftment. In principle, neurons have to fulfill three basic functions: receive incoming signals via synapses, compute and forward processed information to other neurons or effector cells. It is anticipated that functionally integrating stem cell-derived donor neurons perform accordingly. Here we provide protocols for the efficient electrophysiological evaluation of engrafted cells and highlight current limitations thereof.

Bone morphogenetic protein-mediated modulation of lineage diversification during neural differentiation of embryonic stem cells.

Embryonic stem cells (ES cells) can give rise to a broad spectrum of neural cell types. The biomedical application of ES cells will require detailed knowledge on the role of individual factors modulating fate specification during in vitro differentiation. Bone morphogenetic proteins (BMPs) are known to exert a multitude of diverse differentiation effects during embryonic development. Here, we show that exposure to BMP2 at distinct stages of neural ES cell differentiation can be used to promote specific cell lineages. During early ES cell differentiation, BMP2-mediated inhibition of neuroectodermal differentiation is associated with an increase in mesoderm and smooth muscle differentiation. In fibroblast growth factor 2-expanded ES cell-derived neural precursors, BMP2 supports the generation of neural crest phenotypes, and, within the neuronal lineage, promotes distinct subtypes of peripheral neurons, including cholinergic and autonomic phenotypes. BMP2 also exerts a density-dependent promotion of astrocyte differentiation at the expense of oligodendrocyte formation. Experiments involving inhibition of the serine threonine kinase FRAP support the notion that these effects are mediated via the JAK/STAT pathway. The preservation of diverse developmental BMP2 effects in differentiating ES cell cultures provides interesting prospects for the enrichment of distinct neural phenotypes in vitro.

High-purity lineage selection of embryonic stem cell-derived neurons.

The derivation of somatic cell types from pluripotent and self-renewing embryonic stem (ES) cells offers attractive prospects for basic research, compound development, and regenerative medicine. A key prerequisite for biomedical applications of ES cells is the ability to differentiate and isolate defined somatic cell populations at high purity. In this study, we explore the potential of the Talpha1- enhanced green fluorescent protein (EGFP) transgene and polysialic acid (PSA)-neural cell adhesion molecule (NCAM) as lineage selection markers for the derivation of ES cell-derived neurons. Upon controlled in vitro differentiation, ES cells engineered to express EGFP under control of the Talpha1-tubulin promoter exhibited exclusive transgene expression in neurons. Similarly, PSA-NCAM expression during the early stages of ES cell differentiation was restricted to neuronal progeny. Talpha1- EGFP- and PSA-NCAM-positive neurons comprised both inhibitory and excitatory phenotypes. Compared to Talpha1-EGFP, the expression of PSA-NCAM was initiated at slightly earlier stages of neural differentiation. FACSorting of Talpha1-EGFP-positive cells and immunopanning of PSA-NCAMexpressing cells yielded neuronal populations at purities up to 99.6% and 96.9%, respectively. These findings depict Talpha1-EGFP and PSA-NCAM as suitable markers for high-purity selection of early ES cell-derived neurons.

Functional integration of embryonic stem cell-derived neurons in vivo.

Pluripotency and the potential for continuous self-renewal make embryonic stem (ES) cells an attractive donor source for neuronal cell replacement. Despite recent encouraging results in this field, little is known about the functional integration of transplanted ES cell-derived neurons on the single-cell level. To address this issue, ES cell-derived neural precursors exhibiting neuron-specific enhanced green fluorescent protein (EGFP) expression were introduced into the developing brain. Donor cells implanted into the cerebral ventricles of embryonic rats migrated as single cells into a variety of brain regions, where they acquired complex morphologies and adopted excitatory and inhibitory neurotransmitter phenotypes. Synaptic integration was suggested by the expression of PSD-95 (postsynaptic density-95) on donor cell dendrites, which in turn were approached by multiple synaptophysin-positive host axon terminals. Ultrastructural and electrophysiological data confirmed the formation of synapses between host and donor cells. Ten to 21 d after birth, all EGFP-positive donor cells examined displayed active membrane properties and received glutamatergic and GABAergic synaptic input from host neurons. These data demonstrate that, at the single-cell level, grafted ES cell-derived neurons undergo morphological and functional integration into the host brain circuitry. Antibodies to the region-specific transcription factors Bf1, Dlx, En1, and Pax6 were used to explore whether functional donor cell integration depends on the acquisition of a regional phenotype. Our data show that incorporated neurons frequently exhibit a lacking or ectopic expression of these transcription factors. Thus, the lack of an appropriate regional "code" does not preclude morphological and synaptic integration of ES cell-derived neurons.

Functional network integration of embryonic stem cell-derived astrocytes in hippocampal slice cultures.

Embryonic stem (ES) cells provide attractive prospects for neural transplantation. So far, grafting strategies in the CNS have focused mainly on neuronal replacement. Employing a slice culture model, we found that ES cell-derived glial precursors (ESGPs) possess a remarkable capacity to integrate into the host glial network. Following deposition on the surface of hippocampal slices, ESGPs actively migrate into the recipient tissue and establish extensive cell-cell contacts with recipient glia. Gap junction-mediated coupling between donor and host astrocytes permits widespread delivery of dye from single donor cells. During maturation, engrafted donor cells display morphological, immunochemical and electrophysiological properties that are characteristic of differentiating native glia. Our findings provide the first evidence of functional integration of grafted astrocytes, and depict glial network integration as a potential route for widespread transcellular delivery of small molecules to the CNS.