Wei Cui

Differentiation of Human Embryonic Stem Cells to Neural Lineages in Adherent Culture by Blocking Bone Morphogenetic Protein Signaling

Human embryonic stem cells (hESCs) have extensive self‐renewal capacity and are competent to differentiate into any cell type of the body. They are valuable not only for the study of early human development but also for regenerative medicine. However, how to direct differentiation of hESCs along a particular lineage pathway to a specific cell type remains a challenge. Although hESCs have been shown to differentiate in vitro into neural progenitors, the factors controlling their differentiation are poorly understood. In this study, we report the development of an in vitro adherent culture system to efficiently generate neural progenitors in which neither multicellular aggregates nor stromal cells are required. We show that inhibition of bone morphogenetic protein signaling by its antagonist noggin is sufficient to block extraembryonic cell fate, transiently sustain Oct4 gene expression, and result in robust production of neural progenitors. Our findings will provide a platform for studying the molecular mechanism controlling neural differentiation.

Stably Transfected Human Embryonic Stem Cell Clones Express OCT4‐Specific Green Fluorescent Protein and Maintain Self‐Renewal and Pluripotency

Human embryonic stem cells (hESCs) are derived from the inner cell mass of preimplantation embryos; they can be cultured indefinitely and differentiated into many cell types in vitro. These cells therefore have the ability to provide insights into human disease and provide a potential unlimited supply of cells for cell‐based therapy. Little is known about the factors that are important for maintaining undifferentiated hESCs in vitro, however. As a tool to investigate these factors, transfected hES clonal cell lines were generated; these lines are able to express the enhanced green fluorescent protein (EGFP) reporter gene under control of the OCT4 promoter. OCT4 is an important marker of the undifferentiated state and a central regulator of pluripotency in ES cells. These OCT4‐EGFP clonal cell lines exhibit features similar to parental hESCs, are pluripotent, and are able to produce all three embryonic germ layer cells. Expression of OCT4‐EGFP is colocalized with endogenous OCT4, as well as the hESC surface antigens SSEA4 and Tra‐1‐60. In addition, the expression is retained in culture for an extensive period of time. Differentiation of these cells toward the neural lineage and targeted knockdown of endogenous OCT4 expression by RNA interference downregulated the EGFP expression in these cell lines, and this correlates closely with the reduction of endogenous OCT4 expression. Therefore, these cell lines provide an easy and noninvasive method to monitor expression of OCT4 in hESCs, and they will be invaluable for studying not only OCT4 function in hESC self‐renewal and differentiation but also the factors required for maintenance of undifferentiated hESCs in culture.

Distinctive nuclear organisation of centromeres and regions involved in pluripotency in human embryonic stem cells

Nuclear organisation is thought to be important in regulating gene expression. Here we investigate whether human embryonic stem cells (hES) have a particular nuclear organisation, which could be important for maintaining their pluripotent state. We found that whereas the nuclei of hES cells have a general gene-density-related radial organisation of chromosomes, as is seen in differentiated cells, there are also distinctive localisations for chromosome regions and gene loci with a role in pluripotency. Chromosome 12p, a region of the human genome that contains clustered pluripotency genes including NANOG, has a more central nuclear localisation in ES cells than in differentiated cells. On chromosome 6p we find no overall change in nuclear chromosome position, but instead we detect a relocalisation of the OCT4 locus, to a position outside its chromosome territory. There is also a smaller proportion of centromeres located close to the nuclear periphery in hES cells compared to differentiated cells. We conclude that hES cell nuclei have a distinct nuclear architecture, especially at loci involved in maintaining pluripotency. Understanding this level of hES cell biology provides a framework within which other large-scale chromatin changes that may accompany differentiation can be considered.

Inducible ablation of astrocytes shows that these cells are required for neuronal survival in the adult brain

To study the function of astrocytes in the adult brain, we have targeted the expression of E. coli nitroreductase (NTR) to the astrocytes of transgenic mice under the control of the GFAP promoter. The astrocytes expressing NTR were selectively ablated after administration of the prodrug CB1954, resulting in motor discoordination. Histological examination showed that the region most affected in the brain was the cerebellum, in which the Bergmann glia were eliminated and the granular neurons had degenerated. Specific effects were also noted on the dendrites of the Purkinje cells, and the junction between these neurons and granular layer was disrupted. Astrocyte ablation was associated with a dramatic decrease in the expression of glutamate transporters, which may account for the degeneration of granular neurons since the excitotoxic effects of glutamate result in a similar phenotype. These results provide the first evidence that astrocytes are important for the survival of neurons in the adult brain in vivo. GLIA 34:272–282, 2001.

Proliferative lifespan is conserved after nuclear transfer

Cultured primary cells exhibit a finite proliferative lifespan, termed the Hayflick limit. Cloning by nuclear transfer can reverse this cellular ageing process and can be accomplished with cultured cells nearing senescence. Here we describe nuclear transfer experiments in which donor cell lines at different ages and with different proliferative capacities were used to clone foetuses and animals from which new primary cell lines were generated. The rederived lines had the same proliferative capacity and rate of telomere shortening as the donor cell lines, suggesting that these are innate, genetically determined, properties that are conserved by nuclear transfer.

Telomerase-Immortalized Sheep Fibroblasts Can Be Reprogrammed by Nuclear Transfer to Undergo Early Development

Abstract Telomere shortening and lack of telomerase activity have been implicated in cellular senescence in human fibroblasts. Expression of the human telomerase catalytic reverse transcriptase subunit (hTERT) in these cells reconstitutes telomerase activity and immortalizes the cells without tumor transformation. In this report, we show that sheep fibroblasts are similar to human cells. They do not have detectable telomerase activity and undergo only a finite numbers of cell divisions before replicative senescence. Telomere lengths in sheep fibroblasts are similar to those reported for human cells and shorten at a rate of 50–200 base pairs (bp) each cell division. Expression of the human telomerase catalytic subunit restored the telomerase activity in the sheep cells and extended their proliferative life span. None of the telomerase positive sheep fibroblasts exhibited a transformed phenotype after 200 days of continuous culture, and the higher hTERT expressing cells maintained their telomere lengths and normal cell characteristics for more than 500 days in culture. In cloning experiments using one of these cell lines as a nuclear donor, the reconstructed karyoplasts were reprogrammed and developed to the blastocyst stage at a similar frequency to that observed with the parental, telomerase negative cell line. After embryo transfer the blastocysts exhibited a relatively high frequency of implantation, early fetal development, and organogenesis. No fetuses survived beyond 40 days of development, however, showing that although these cells could be substantially reprogrammed, they were not fully competent for nuclear transfer.

Inhibition of myc-dependent breast tumor formation in transgenic mice

One of the most promising approaches for cancer gene therapy is the use of the so-called suicide genes, which encode prodrug-activating enzymes and render transduced cells more sensitive to prodrugs. The enzyme nitroreductase (NTR) converts prodrug CB1954 into a cytotoxic DNA interstrand cross-linking agent. We have established transgenic mice in which the pro-oncogene c-myc and NTR were fused to the internal ribosome entry site and co-expressed in luminal cells of the mammary gland under the control of mouse whey acidic protein (WAP) promoter to evaluate NTR mediated ablation of mammary tumors. More than 78% of transgenic females developed in situ or infiltrating carcinomas after three to four pregnancies. By contrast, if the transgenic female mice were given the prodrug CB1954 during their third lactation, the incidence of tumors decreased to less than 40% (Pu2009<u20090.05). The total number of carcinomas was even more striking with 117 carcinomas identified in 14 non-ablated transgenics compared with only five in 15 treated animals (pu2009<u20090.05, student t test). C-myc induced pleomorphic nuclei and mitotic figures were seen as a field change in over 70% of the untreated transgenics compared to 20% in the treated group. Our results suggest that the enzyme pro-drug system NTR-CB1954 efficiently inhibit myc-dependent tumor formation and malignant progression in the mammary gland.