Ana Villa

Establishment and properties of a growth factor-dependent, perpetual neural stem cell line from the human CNS.

The ready availability of unlimited quantities of neural stem cells derived from the human brain holds great interest for basic and applied neuroscience, including therapeutic cell replacement and gene transfer following transplantation. We report here the combination of epigenetic and genetic procedures for perpetuating human neural stem cell lines. Thus we tested various culture conditions and genes for those that optimally allow for the continuous, rapid expansion and passaging of human neural stem cells. Among them, v-myc (the p110 gag-myc fusion protein derived from the avian retroviral genome) seems to be the most effective gene; we have also identified a strict requirement for the presence of mitogens (FGF-2 and EGF) in the growth medium, in effect constituting a conditional perpetuality or immortalization. A monoclonal, nestin-positive, human neural stem cell line (HNSC.100) perpetuated in this way divides every 40 h and stops dividing upon mitogen removal, undergoing spontaneous morphological differentiation and upregulating markers of the three fundamental lineages in the CNS (neurons, astrocytes, and oligodendrocytes). HNSC.100 cells therefore retain basic features of epigenetically expanded human neural stem cells. Clonal analysis confirmed the stability, multipotency, and self-renewability of the cell line. Finally, HNSC.100 can be transfected and transduced using a variety of procedures and genes encoding proteins for marking purposes and of therapeutic interest (e.g., human tyrosine hydroxylase I).

Genetically Perpetuated Human Neural Stem Cells Engraft and Differentiate into the Adult Mammalian Brain

Human neural stem cells (HNSCs) may serve as a cellular vehicle for molecular therapies as well as for cell replacement in the human CNS. The survival, integration, and differentiation of HNSC.100, a multipotent cell line of HNSCs (A. Villa et al. (2000), Exp. Neurol. 161, 67-84), conditionally perpetuated by genetic and epigenetic means, was investigated after transplantation to the striatum and substantia nigra of the adult, intact rat brain. These are two key regions in the mammalian brain involved in the control of voluntary movement and motor coordination, among other functions. Soon after transplantation (1 week), the cells had already integrated in a nondisruptive manner into the surrounding tissue and migrated out of the implantation site to different distances depending on graft location (in the range of 0.5-2.5 mm). Cell migration was markedly more extensive in the striatum, where the cells colonized the whole extent of the caudate-putamen, than in the substantia nigra region. The engrafted cells completely downregulated the stem cell marker nestin and, due to their multipotential nature, differentiated and expressed mature neural markers. As expected from cells grafted into nonneurogenic regions of the intact brain, the majority of differentiated cells expressed GFAP (astroglia), but expression of other markers, like GalC (oligodendroglia) and MAP2, beta-tubulin III, NeuN, and NSE (for mature neurons) could also be detected. These results demonstrate that genetically perpetuated HNSCs, once transplanted, find residence in the host brain, where they differentiate, generating mature neural cells in the host, chimeric, adult mammalian brain. HNSCs cell lines may be a highly useful model for the development of humanized systems for cell replacement and/or gene transfer to the CNS, which will likely be strong candidates for future therapeutic application in human neurodegenerative conditions.

Human Neural Stem and Progenitor Cells: In Vitro and In Vivo Properties, and Potential for Gene Therapy and Cell Replacement in the CNS

The generation of unlimited quantities of neural stem and/or progenitor cells derived from the human brain holds great interest for basic and applied neuroscience. In this article we critically review the origins and recent developments of procedures developed for the expansion, perpetuation, identification, and isolation of human neural precursors, as well as their attributes. Factors influencing their in vitro properties, both under division and after differentiation conditions, are evaluated, with the aim of identifying properties common to the different culture systems reported. This analysis suggests that different culture procedures result in cells with different properties, or even in different cells being isolated. With respect to in vivo performance, present evidence obtained in rodents indicate that cultured human neural precursors, in general, are endowed with excellent integrative properties. Differentiation of the implanted cells, in particular in the case of adult recipients, seems not to be complete, and functionality still needs to be demonstrated. In relation to gene transfer and therapy, aspects currently underexplored, initial data support the view that human neural stem and progenitor cells may serve a role as a platform cell for the delivery of bioactive substances to the diseased CNS. Although a large deal of basic research remains to be done, available data illustrate the enormous potential that human neural precursors isolated, expanded, and characterized in vitro hold for therapeutic applications. In spite of this potential, maintaining a critical view on many unresolved questions will surely help to drive this research field to a good end, that is, the development of real therapies for diseases of the human nervous system.

Human neural progenitor cells: better blue than green?

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Generation and properties of a new human ventral mesencephalic neural stem cell line

Neural stem cells (NSCs) are powerful research tools for the design and discovery of new approaches to cell therapy in neurodegenerative diseases like Parkinsons disease. Several epigenetic and genetic strategies have been tested for long-term maintenance and expansion of these cells in vitro. Here we report the generation of a new stable cell line of human neural stem cells derived from ventral mesencephalon (hVM1) based on v-myc immortalization. The cells expressed neural stem cell and radial glia markers like nestin, vimentin and 3CB2 under proliferation conditions. After withdrawal of growth factors, proliferation and expression of v-myc were dramatically reduced and the cells differentiated into astrocytes, oligodendrocytes and neurons. hVM1 cells yield a large number of dopaminergic neurons (about 12% of total cells are TH+) after differentiation, which also produce dopamine. In addition to proneural genes (NGN2, MASH1), differentiated cells show expression of several genuine mesencephalic dopaminergic markers such as: LMX1A, LMX1B, GIRK2, ADH2, NURR1, PITX3, VMAT2 and DAT, indicating that they retain their regional identity. Our data indicate that this cell line and its clonal derivatives may constitute good candidates for the study of development and physiology of human dopaminergic neurons in vitro, and to develop tools for Parkinsons disease cell replacement preclinical research and drug testing.

Age-related changes in calcium homeostatic mechanisms in synaptosomes in relation with working memory deficiency.

Aging is associated with alterations in different systems that govern neuronal calcium homeostasis. This study was designed to determine whether any of these alterations may contribute to the decline in spatial working memory that is observed in old rats. Several parameters [initial (5 s) and steady state (15 min) 45Ca2+ uptake, FCCP-releaseable 45Ca2+, [Ca2+]i levels, depolarization-induced phosphoprotein (P97, PP65, P42) dephosphorylation and acetylcholine levels and release) involved in calcium homeostasis/signaling were determined in whole brain synaptosomes derived from adult (9-month-old) and old (24-month-old) rats that were evaluated for spatial memory performance in the eight-arm radial maze. The neurochemical analysis indicated that both the 9- and 24-month-old rats were impaired with respect to 3-month-old animals. When learners (animals reaching criterion; RC) were compared to memory impaired rats (MI), it was found that the FCCP-releaseable 45Ca2+ of synaptosomes, that reflects mitochondrial calcium, was lower in the MI than the RC rats and was correlated with the behavioral performance of the rats in their first testing sessions. The results suggest that the loss of calcium uptake capacity in synaptic mitochondria during aging may be associated with impaired working memory in old animals.

Human neural stem cells in vitro. A focus on their isolation and perpetuation

Because of their ability to generate all the cell types in the nervous system, neural stem cells are promising candidates for the development of cellular and genetic therapies for nervous system disorders and, in particular, neurodegenerative diseases. In recent years, researchers have discovered ways of expanding and perpetuating these cells in culture, as well as different sources for these tissue-specific stem cells, ranging from embryonic to adult tissue, and also from human pluripotent stem cells. Current efforts are oriented to the understanding of the molecular mechanisms controlling their fate decisions, their genetic engineering, and how to harness their potential to make them useful from a therapeutic point of view.

Genetic perpetuation of in vitro expanded human neural stem cells: cellular properties and therapeutic potential.

Long-term propagated human neural stem cells (self-renewing and multipotent) allow for the unlimited and predictable generation of different types of human neural cells in vitro. In addition, these cell lines may be of help for the elucidation of basic neuro-developmental issues, and also for the development of innovative therapeutic strategies for nervous system disorders (through cell replacement and/or gene transfer-based therapies). In this article we summarize our current knowledge about these long-term cultured cells, particularly that of immortalized cells, with the aim of critically addressing their usefulness and potential for therapeutic use. Perpetuation methods and in vitro properties of immortalized cells are analyzed. Although reports on in vivo studies are scarce, present data on survival, integration, migration, and differentiation of the cells indicate that they may be useful for the development of cellular and genetic therapies, in various models of neurodegeneration. A great deal of basic and applied research remains to be done in order to fully explore, understand, and exploit the therapeutic potential of human neural precursor cells.

Gene marking of human neural stem/precursor cells using green fluorescent proteins

Ex vivo gene therapy and cell replacement in the nervous system may provide therapeutic opportunities for neurodegenerative disorders. The development of optimal gene marking procedures for human neural stem cells (hNSCs) is crucial for the success of these strategies, in order to provide a correct understanding of the biology of transplanted cells.

Low-Level Tyrosine Hydroxylase (TH) Expression Allows for the Generation of Stable TH+ Cell Lines of Human Neural Stem Cells

Genetic engineering of neurotransmitter metabolic routes is important for the development of neurotransmitter-producing cells for the ex vivo gene therapy of many CNS diseases. Human neural stem cells (hNSCs) are excellent candidates to serve this role, but, for the case of Parkinsons disease, the cells do not normally express the rate-limiting dopamine (DA) synthesis enzyme tyrosine hydroxylase (TH), and are not equipped with the detoxifying mechanisms needed to prevent the neurotoxicity associated with the DA phenotype. In this study we have examined the capacity of hNSCs for ectopic expression of human TH. High-level TH expression (from viral promoters) leads to growth arrest and hNSC death (associated with an increase in p53 expression and nuclear fragmentation), which can be counteracted by treatment with a pan-caspase inhibitor. As a consequence, stable TH-expressing hNSC sublines could not be derived using viral promoters. In contrast, moderate TH expression (from a human housekeeping promoter, polyubiquitin gene), allows for stable TH+ subclone derivation, seemingly originating from low-expressing cells. Our results are thus compatible with the view that stable TH-expressing hNSC lines can be generated if TH expression levels are kept at a moderate level, and that the goal normally set of aiming at high-level TH expression may need to be reconsidered. These results may be relevant for the generation of TH/DA-producing human neural cells for in vitro and neurotransplantation research in Parkinsons disease.