Novel Culture Strategies and Signal Transduction Pathways of Pluripotent Stem Cells

Pluripotent stem cells (PSCs) can self-renew indefinitely in culture while maintaining their capacity to differentiate into any cell type of an organism, thus offering novel sources for drug screening, in vitro disease modelling, and cell replacement therapies. However, due to their sensitive nature, many PSC lines are still cultured using undefined components such as serum or serum-derived components, on either feeder cells or complex protein mixes such as Matrigel or gelatine. In order to fully realize the potential of these cells we need controlled, completely defined and xeno-free culturing conditions that maintain growth and survival of homogenous, non-differentiated colonies. This thesis focuses on the in vitro maintenance of both mouse and human PSCs, analysing the media and substrate requirements of these cells and linking them to the intracellular signalling pathways involved in the maintenance of pluripotency and self-renewal. Benchmarking of commercially available culture methods for PSCs has been performed, evaluating their capacity to maintain pluripotency and growth of undifferentiated PSCs over several passages and reporting new characteristics, like the tendency of mouse PSCs to grow as floating spheres in 2i medium, a novel media formulation that uses two inhibitors to hinder differentiation capacity and subsequently induce pure, undifferentiated cultures. The major finding in this thesis is the identification of Inter-α-Inhibitor (IαI) as a protein able to activate the previously described signal-transduction pathway Yes/YAP/TEAD in mouse PSCs and to induce transcription of the well-known stem cell transcription factors Nanog and Oct3/4. IαI is a serum protein found in high concentration in human serum that had been traditionally described as an extracellular matrix remodelling protein. For the first time, we describe IαI to have signalling capacity on PSCs. Moreover, IαI is demonstrated to induce attachment, growth and long-term survival of undifferentiated mouse and human PSCs when added to serum-free, chemically defined media. IαI is the first molecule described to date to induce attachment of human PSCs on uncoated, standard tissue-culture treated plastic, just by supplementation as a soluble molecule at the seeding step. Following this discovery, we evaluate a novel culture method using the completely defined, serum-free E8 medium supplemented with IαI (E8:IαI) for long-term propagation of four different human PSC lines and discover