Cheryl E. Marshall scite author profile

Our ability to use human embryonic stem (hES) cells in cell replacement therapy for Parkinson's disease depends on the discovery of ways to simply and reliably differentiate a dopaminergic (DA) phenotype in these cells. Although several protocols exist for the differentiation of DA traits in hES, they involve the prolonged use of complex media with undefined components, cell conditioned media and/or co-culture with various cells, usually of animal origin. In this study, several well-characterized (H9, BG01) and several new uncharacterized (HUES7, HUES8) hES cell lines were studied for their capacity to differentiate into DA neurons in culture using a novel rapid protocol which uses only chemically-defined human-derived media additives and substrata. Within 3 weeks, cells from all 4 cell lines progressed from the undifferentiated state to β-tubulin III positive cells expressing DA markers in vitro. Moreover, transplantation of these cells into the striata of 6-hydroxydopaminetreated rats at the neuronal progenitor stage resulted in the appearance of differentiated DA traits in vivo 2-3 weeks later.

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Studies on the Differentiation of Dopaminergic Traits in Human Neural Progenitor Cells in Vitro and in Vivo

Yang

Donaldson

Marshall

et al. 2004

Cell Transplant

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The development of cell replacement therapies for the treatment of neurodegenerative disorders such as Parkinson's disease (PD) may depend upon the successful differentiation of human neural stem/progenitor cells into dopamine (DA) neurons. We show here that primary human neural progenitors (HNPs) can be expanded and maintained in culture both as neurospheres (NSPs) and attached monolayers where they develop into neurons and glia. When transplanted into the 6-hydroxydopamine-lesioned rat striatum, undifferentiated NSPs survive longer (60% graft survival at 8-16 weeks vs. 30% graft survival at 8-13 weeks) and migrate farther than their attached counterparts. While both NSP and attached cells continue to express neuronal traits after transplantation, the spontaneous expression of differentiated transmitter-related traits is not observed in either cell type. However, following predifferentiation in culture using a previously described cocktail of reagents, approximately 25% of HNPs can permanently express the DA enzyme tyrosine hydroxylase (TH), even following replating and removal of the DA differentiation cocktail. When these predifferentiated HNPs are transplanted into the brain, however, TH staining is not observed, either because expression is lost or TH-expressing cells preferentially die. Consistent with the latter view is a decrease in total cell survival and migration, and an enhanced glial response in these grafts. In contrast, we found that the overall survival of HNPs is improved when cells engraft near blood vessels or CSF compartments or when they are placed into an intact unlesioned brain, suggesting that there are factors, as yet unidentified, that can better support the development of engrafted HNPs.

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Transient Differentiation of Adult Human Bone Marrow Cells into Neuron-like Cells in Culture: Development of Morphological and Biochemical Traits Is Mediated by Different Molecular Mechanisms

Suon

Jin

Donaldson

et al. 2004

Stem Cells and Development

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Studies on rodent bone marrow stromal cells (MSCs) have revealed a capacity, for at least a portion of cells, to express neuron-like traits after differentiation in culture. Little, however, is known about the ability of human MSCs in this regard. We show here that incubation with certain differentiation cocktails, particularly those that include reagents that increase cellular cAMP levels, produces a rapid (1-4 h) and transient (24-48 h) transformation of nearly all hMSCs into neuron-like cells displaying a complex network of processes using phase or scanning electron microscopic optics. In addition, differentiated human (h) MSCs express increased quantities of neuron-[β-tubulin III, neurofilament (NF), neuronal-specific enolase (NSE)] and glial-[glial fibrillary acidic protein (GFAP)] specific proteins and mRNAs, which are also expressed in low levels in undifferentiated MSCs. In contrast, the mesenchymal marker, fibronectin, which is highly expressed in the undifferentiated state, is reduced following differentiation. These biochemical changes, but not the acquisition of a neuronlike appearance, are partially inhibited by incubation of hMSCs with protein (cycloheximide) and mRNA (actinomycin D) synthesis inhibitors with differentiating reagents. Only incubation with 100 ng/ml colchicine, which disrupts the microtubular cytoskeleton, prevents the conversion of hMSCs into neuron-like cells. These results demonstrate that hMSCs acquire the morphological appearance and the biochemical makeup typical of neurons by independently regulated mechanisms.

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