Stefanie Terstegge

Cancer Genes Hypermethylated in Human Embryonic Stem Cells

Developmental genes are silenced in embryonic stem cells by a bivalent histone-based chromatin mark. It has been proposed that this mark also confers a predisposition to aberrant DNA promoter hypermethylation of tumor suppressor genes (TSGs) in cancer. We report here that silencing of a significant proportion of these TSGs in human embryonic and adult stem cells is associated with promoter DNA hypermethylation. Our results indicate a role for DNA methylation in the control of gene expression in human stem cells and suggest that, for genes repressed by promoter hypermethylation in stem cells in vivo, the aberrant process in cancer could be understood as a defect in establishing an unmethylated promoter during differentiation, rather than as an anomalous process of de novo hypermethylation.

MicroRNA-Based Promotion of Human Neuronal Differentiation and Subtype Specification

MicroRNAs are key regulators of neural cell proliferation, differentiation and fate choice. Due to the limited access to human primary neural tissue, the role of microRNAs in human neuronal differentiation remains largely unknown. Here, we use a population of long-term self-renewing neuroepithelial-like stem cells (lt-NES cells) derived from human embryonic stem cells to study the expression and function of microRNAs at early stages of human neural stem cell differentiation and neuronal lineage decision. Based on microRNA expression profiling followed by gain- and loss-of-function analyses in lt-NES cells and their neuronal progeny, we demonstrate that miR-153, miR-324-5p/3p and miR-181a/a* contribute to the shift of lt-NES cells from self-renewal to neuronal differentiation. We further show that miR-125b and miR-181a specifically promote the generation of neurons of dopaminergic fate, whereas miR-181a* inhibits the development of this neurotransmitter subtype. Our data demonstrate that time-controlled modulation of specific microRNA activities not only regulates human neural stem cell self-renewal and differentiation but also contributes to the development of defined neuronal subtypes.

Laser-Assisted Photoablation of Human Pluripotent Stem Cells from Differentiating Cultures

Due to their pluripotency and their self-renewal capacity, human pluripotent stem cells (hPSC) provide fascinating perspectives for biomedical applications. In the long term, hPSC-derived tissue-specific cells will constitute an important source for cell replacement therapies in non-regenerative organs. These therapeutic approaches, however, will critically depend on the purity of the in vitro differentiated cell populations. In particular, remaining undifferentiated hPSC in a transplant can induce teratoma formation. In order to address this challenge, we have developed a laser-based method for the ablation of hPSC from differentiating cell cultures. Specific antibodies were directed against the hPSC surface markers tumor related antigen (Tra)-1-60 and Tra-1-81. These antibodies, in turn, were targeted with nanogold particles. Subsequent laser exposure resulted in a 98,9 ± 0,9% elimination of hPSCs within undifferentiated cell cultures. In order to study potential side effects of laser ablation on cells negative for Tra-1-60 and Tra-1-81, hPSC were mixed with GFP-positive hPSC-derived neural precursors (hESCNP) prior to ablation. These studies showed efficient elimination of hPSC while co-treated hESCNP maintained their normal proliferation and differentiation potential. In vivo transplantation of treated and untreated mixed hPSC/hESCNP cultures revealed that laser ablation can dramatically reduce the risk of teratoma formation. Laser-assisted photothermolysis thus represents a novel contact-free method for the efficient elimination of hPSC from in vitro differentiated hPSC-derived somatic cell populations.

Laser-assisted selection and passaging of human pluripotent stem cell colonies

The derivation of somatic cell products from human embryonic stem cells (hESCs) requires a highly standardized production process with sufficient throughput. To date, the most common technique for hESC passaging is the manual dissection of colonies, which is a gentle, but laborious and time-consuming process and is consequently inappropriate for standardized maintenance of hESC. Here, we present a laser-based technique for the contact-free dissection and isolation of living hESCs (laser microdissection and pressure catapulting, LMPC). Following LMPC treatment, 80.6+/-8.7% of the cells remained viable as compared to 88.6+/-1.7% of manually dissected hESCs. Furthermore, there was no significant difference in the expression of pluripotency-associated markers when compared to the control. Flow cytometry revealed that 83.8+/-4.1% of hESCs isolated by LMPC expressed the surface marker Tra-1-60 (control: 83.9+/-3.6%). In vitro differentiation potential of LMPC treated hESCs as determined by embryoid body formation and multi-germlayer formation was not impaired. Moreover, we could not detect any overt karyotype alterations as a result of the LMPC process. Our data demonstrate the feasibility of standardized laser-based passaging of hESC cultures. This technology should facilitate both colony selection and maintenance culture of pluripotent stem cells.

Nucleofection of Human Embryonic Stem Cells

Human embryonic stem cells (HESCs) are widely used as a model system for human cell type specification. Genetic modification forms a valuable tool for HESC technology, as it provides the basis for lineage selection, i.e., the purification of a specific cell type after differentiation. Electroporation is an efficient way to transfect HESCs. Nucleofection is an electroporation-based transfection technique which utilizes cell-type-specific buffer solutions and specific electric settings. Customization of these two parameters has been proven to result in highly efficient gene transfer even in hard-to-transfect cells. We can show that nucleofection surpasses conventional electroporation in efficiency and decreases the experimental effort for transfection of HESCs.

Correction: MicroRNA-Based Promotion of Human Neuronal Differentiation and Subtype Specification

[This corrects the article DOI: 10.1371/journal.pone.0059011.].

Stem cell technology

Stem cell is the term used to designate those cells of the body that are capable of dividing in their unspecialised form (self renewal) and yet still have the potential to develop into specialised cell types. The process by which stem cells develop into specialised cells devoted to a specific function is known as differentiation. In the course of this process, the immature, undifferentiated cells develop into specialised cells capable of performing one specific function in the adult organism. To reach this point, the stem cell has to pass through a series of differentiation stages. The morphology and function of differentiated cells is very different from that of their progenitor cells, and varies widely from one type of cell to another.