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.

Transduction of human embryonic stem cells by ecotropic retroviral vectors.

The steadily increasing availability of human embryonic stem (hES) cell lines has created strong interest in applying available tools for gene transfer in murine cells to human systems. Here we present a method for the transduction of hES cells with ecotropic retroviral vectors. hES cells were transiently transfected with a construct carrying the murine retrovirus receptor mCAT1. Subsequently, the cells were exposed to replication-deficient Moloney murine leukemia virus (MoMuLV) derivatives or pseudotyped lentiviral vectors. With oncoretroviral vectors, this procedure yields overall transduction efficiencies of up to 20% and permits selection of permanently transduced clones with high frequency. Selected clones maintained expression of pluripotency-associated markers and exhibited multi-germ layer differentiation both in vitro and in vivo. HES cell-derived somatic cells including neural progeny maintained high levels of transgene expression. Lentiviral vectors pseudotyped with the MoMuLV envelope could be introduced in the same manner with efficiencies of up to 33%. Transgene expression of lentivirally transduced hES cells remained permanent after differentiation even without selection pressure. Bypassing the regulatory issues associated with the use of amphotropic retroviral systems and exploiting the large pool of existing murine vectors, this method provides a safe and versatile tool for gene transfer and lineage analysis in hES cells and their progeny.

Nucleofection of human embryonic stem cells.

Human embryonic stem (hES) cells provide an important tool for the study of human development, disease, and tissue regeneration. Technologies for efficient genetic modification are required to exploit hES cells fully for these applications. Here we present a customized protocol for the transfection of hES cells with the Nucleofector technology and compare its efficiency with conventional electroporation and lipofection. Cell survival and transfection efficiency were quantified using an enhanced green fluorescent protein (EGFP) reporter construct. Our optimized nucleofection parameters yielded survival rates >70%. Under these conditions, 66% of the surviving cells showed transgene expression 24 h after nucleofection. Transfected cells maintained expression of the pluripotency- associated markers Tra-1-60, Tra-1-81, and Oct4 and could be expanded to stably transgene-expressing clones. The low quantities of hES cells and DNA required for nucleofection could make this method an attractive tool for miniaturized high throughput screening (HTS) applications.

Pumilio-2 function in the mouse nervous system.

Coordinated mRNA translation at the synapse is increasingly recognized as a critical mechanism for neuronal regulation. Pumilio, a translational regulator, is known to be involved in neuronal homeostasis and memory formation in Drosophila. Most recently, the mammalian Pumilio homolog Pumilio-2 (Pum2) has been found to play a role in the mammalian nervous system, in particular in regulating morphology, arborization and excitability of neuronal dendrites, in vitro. However, the role of Pum2 in vivo remains unclear. Here, we report our investigation of the functional and molecular consequences of Pum2 disruption in vivo using an array of neurophysiology, behavioral and gene expression profiling techniques. We used Pum2-deficient mice to monitor in vivo brain activity using EEG and to study behavior traits, including memory, locomotor activity and nesting capacities. Because of the suspected role of Pum2 in neuronal excitability, we also examined the susceptibility to seizure induction. Finally, we used a quantitative gene expression profiling assay to identify key molecular partners of Pum2. We found that Pum2-deficient mice have abnormal behavioral strategies in spatial and object memory test. Additionally, Pum2 deficiency is associated with increased locomotor activity and decreased body weight. We also observed environmentally-induced impairment in nesting behavior. Most importantly, Pum2-deficient mice showed spontaneous EEG abnormalities and had lower seizure thresholds using a convulsing dosage of pentylenetetrazole. Finally, some genes, including neuronal ion channels, were differentially expressed in the hippocampus of Pum2-deficient mice. These findings demonstrate that Pum2 serves key functions in the adult mammalian central nervous system encompassing neuronal excitability and behavioral response to environmental challenges.

Site-specific recombination in human embryonic stem cells induced by cell-permeant Cre recombinase.

The biomedical application of human embryonic stem (hES) cells will increasingly depend on the availability of technologies for highly controlled genetic modification. In mouse genetics, conditional mutagenesis using site-specific recombinases has become an invaluable tool for gain- and loss-of-function studies. Here we report highly efficient Cre-mediated recombination of a chromosomally integrated loxP-modified allele in hES cells and hES cell-derived neural precursors by protein transduction. Recombinant modified Cre recombinase protein translocates into the cytoplasm and nucleus of hES cells and subsequently induces recombination in virtually 100% of the cells. Cre-transduced hES cells maintain the expression of pluripotency markers as well as the capability of differentiating into derivatives of all three germ layers in vitro and in vivo. We expect this technology to provide an important technical basis for analyzing complex genetic networks underlying human development as well as generating highly purified, transplantable hES cell-derived cells for regenerative medicine.

Hedgehog signaling is required for the differentiation of ES cells into neurectoderm.

Mouse embryonic stem cells can differentiate in vitro into cells of the nervous system, neurons and glia. This differentiation mimics stages observed in vivo, including the generation of primitive ectoderm and neurectoderm in embryoid body culture. We demonstrate here that embryonic stem cell lines mutant for components of the Hedgehog signaling cascade are deficient at generating neurectoderm-containing embryoid bodies. The embryoid bodies derived from mutant cells are also unable to respond to retinoic acid treatment by producing nestin-positive neural stem cells, a response observed in cultures of heterozygous cells, and contain cores apparently arrested at the primitive ectoderm stage. The mutant cultures are also deficient in their capacity to differentiate into mature neurons and glia. These data are consistent with a role for Hedgehog signaling in generating neurectoderm capable of producing the appropriate neuronal and glial progenitors in ES cell culture.