High density cultures of embryonic stem cells.

Embryonic stem cells (ESC) have the unique ability to differentiate into a variety of tissue types. However, the realization of regenerative medicine will require the production of large quantities of ESC which subsequently have to be differentiated into the final phenotype. Thus, we sought to develop a simple and scaleable bioprocess to increase densities of ESC to achieve this goal. Using mouse embryonic stem cells (mESC) as a model, by combining automated feeding and culture of mESC on petriperm dishes, cell densities were enhanced up to 6.4 x 10(6) cells/cm2 compared to conventional petri dish culture which only reached 0.2 to 1.4 x 10(6) cells/cm2. It was found that mESC from all experiments maintained excellent viability, pluripotency, and genetic stability after growing for 6 days in petriperm cultures with automated feeding. The expression of Oct-4 transcription factor was observed in all cultures, mESC formed embryoid bodies in differentiated cultures and teratomas in SCID mice, confirming their pluripotency, and karyotype of the cultures was normal. This culture method was stable for routine passaging and a second mESC cell line was shown to perform in a similar manner on petriperm with automated feeding. This work represents an important step towards achieving high density cultures of ESC.

Expansion of pluripotent human embryonic stem cells on human feeders.

Human embryonic stem cells (HES) hold great potential for regenerative medicine because of their ability to differentiate to any cell type. However, a limitation is that HES cells require a feeder layer to stay undifferentiated. Routinely, mouse embryonic fibroblast is used. However, for therapeutic applications, contamination with mouse cells may be considered unacceptable. In this study, we evaluated three commercially available human foreskin feeder (HF) lines for their ability to support HES cell growth in media supplemented with serum or serum replacer. HES cells on HF in serum replacer-supplemented media were cultured for >30 passages. They remained undifferentiated, maintained a normal karyotype, and continued to be positive for the pluripotent markers Oct-4, SOX-2, SSEA-4, GCTM-2, Tra-1-60, Tra-1-81, and alkaline phosphatase. In vivo, HES cells formed teratomas in SCID mouse models that represent the three embryonic germ layers. In contrast, HES cells cultured on HF in serum-supplemented media differentiated after three passages. Morphologically, the cells became cystic with a loss of intracellular Oct-4. We have successfully adapted and cultured undifferentiated HES cells on three human feeder lines for >30 passages. No difficulties were observed with the exception of serum in the media. This study reveals a safe and accessible source for feeders for HES cell research and potential therapeutic applications.