Osmolar Modulation Drives Reversible Cell Cycle Exit and Human Pluripotent Cell Differentiation via NF-κВ and WNT Signaling

Terminally differentiated cells are commonly regarded as the most stable cell state in adult organisms, characterized by growth arrest while fulfilling their specialized functions. A better understanding of the mechanisms involved in promoting cell cycle exit will improve the ability to differentiate pluripotent cells into mature tissues for both pharmacological and therapeutic use. Here, it demonstrates that a hyperosmolar environment enforces a protective p53-independent quiescent state in immature hepatoma cells and in pluripotent stem cell-derived models of human hepatocytes and endothelial cells. Prolonged culture in hyperosmolar conditions stimulates changes in gene expression promoting functional cell maturation. Interestingly, hyperosmolar conditions do not only trigger growth arrest and cellular maturation but are also necessary to maintain this maturated state, as switching back to plasma osmolarity reverses the changes in expression of maturation and proliferative markers. Transcriptome analysis revealed sequential stages of osmolarity-regulated growth arrest followed by cell maturation, mediated by activation of NF-kappa B, and repression of WNT signaling, respectively. This study reveals that a modulated increase in osmolarity serves as a biochemical signal to promote long-term growth arrest and cellular maturation into different lineages, providing a practical method to generate differentiated hiPSCs that resemble their mature counterpart more closely. In vitro cultures of differentiated cells are often carried out under normosmolar conditions, yet numerous mature tissues naturally exist in higher osmolarity. Cultivating human pluripotent cells under differentiation conditions or hepatoma cell lines shows that physiological hyperosmolarity can trigger cell cycle arrest and transcriptional maturation, two vital features of terminal differentiation, all while avoiding cell damage.image

Automated summary

This study demonstrates that a hyperosmolar environment can induce cell cycle arrest and cellular maturation through the regulation of NF-kappa B and WNT signaling. It provides a practical method for differentiating stem cells and suggests the use of higher osmolarity in in vitro cultures to mimic natural conditions.