Expression of Reg family proteins in embryonic stem cells and its modulation by Wnt/beta-catenin signaling.

Regenerating islet (Reg) proteins are involved in the proliferation and differentiation of diverse cell types. However, whether embryonic stem cells (ESCs) express Reg genes and their corresponding proteins remains unknown. In this study, we probed the expression of Reg family members by mouse ESCs (mESCs). Mouse Reg1 and Reg3gamma were detected in undifferentiated stem cells. Furthermore, we tested if gastrin--an inducer of Reg1 expression in committed cells--up-regulates the Reg1 gene in mESCs. Gastrin did not affect the expression of Reg1 either in self-renewing mESCs or under conditions permitting their differentiation. Moreover, overexpression of Reg genes found in various forms of cancer has been linked to dysregulated activation of the canonical Wnt/beta-catenin cascade. Given the important roles of Wnt signaling in stem cells, we investigated if activation of Wnt alters the expression of Reg genes in mESCs. Wnt activation led to an increase in Reg1 gene expression with a concomitant increase in the amount of secreted Reg1 protein. Finally, the expression pattern of genes indicative of differentiation was examined in mESCs that were either exposed to soluble Reg1 or overexpressed the Reg1 gene. This is the first account of expression of Reg family members by ESCs. Our results show that the canonical Wnt cascade affects Reg expression and warrants further studies into the potential roles of Reg proteins in stem cell physiology.

Scalable stirred-suspension bioreactor culture of human pluripotent stem cells.

Advances in stem cell biology have afforded promising results for the generation of various cell types for therapies against devastating diseases. However, a prerequisite for realizing the therapeutic potential of stem cells is the development of bioprocesses for the production of stem cell progeny in quantities that satisfy clinical demands. Recent reports on the expansion and directed differentiation of human embryonic stem cells (hESCs) in scalable stirred-suspension bioreactors (SSBs) demonstrated that large-scale production of therapeutically useful hESC progeny is feasible with current state-of-the-art culture technologies. Stem cells have been cultured in SSBs as aggregates, in microcarrier suspension and after encapsulation. The various modes in which SSBs can be employed for the cultivation of hESCs and human induced pluripotent stem cells (hiPSCs) are described. To that end, this is the first account of hiPSC cultivation in a microcarrier stirred-suspension system. Given that cultured stem cells and their differentiated progeny are the actual products used in tissue engineering and cell therapies, the impact of bioreactor's operating conditions on stem cell self-renewal and commitment should be considered. The effects of variables specific to SSB operation on stem cell physiology are discussed. Finally, major challenges are presented which remain to be addressed before the mainstream use of SSBs for the large-scale culture of hESCs and hiPSCs.

Propagation of embryonic stem cells in stirred suspension without serum.

Embryonic stem cells (ESCs) with their unlimited capacity for self-renewal and ability to differentiate along multiple cell lineages are a superb starting material for biotechnology applications and cellular therapies. However, realization of the potential of ESCs requires the development of scalable systems for their production in large quantities and in a regulated manner. Here, we describe a methodology for the expansion of mouse ESCs (mESCs) as pluripotent aggregates in a stirred suspension bioreactor and in medium without serum. Initially, the culture of feeder cell-independent mESCs in dishes was adapted to serum-free conditions. Also, we explored whether spinner flasks equipped with a triangle-shaped impeller and baffles support the culture of mESC aggregates. Serum-free culture in these vessels resulted in an almost 20-fold increase in the live mESC concentration over 4 days without significant loss of cell viability. Even after consecutive passages, mESCs retained high expression of pluripotency markers Oct3/4, Rex1 and SSEA-1. More importantly, when differentiation was induced these cells adopted fates of all three germ layers namely neuroectoderm, cardiac mesoderm and definitive endoderm. These findings demonstrate that stem cells can be propagated under serum-free conditions in a scalable stirred-suspension culture without loss of their pluripotency.