Differentiation requires coordinated exit from the stem cell state, during which gene regulatory networks sustaining self-renewal are dismantled, while lineage-specific programs are activated. This transition is governed by chromatin modifications, transcriptional networks, RNA processing, translational control, and metabolic rewiring that must operate with temporal precision. Despite significant progress in identifying individual regulatory components, understanding how these layers integrate to orchestrate irreversible cell fate commitment remains a fundamental challenge. This review examines common and unique regulatory principles governing stem cell exit, from totipotency during early embryogenesis to tissue-specific stem cell differentiation in adults. We synthesize recent findings on regulatory mechanisms across mammalian species, highlight species-specific adaptations, and explore the concept of reversibility in differentiation. Elucidating these principles has broad implications for regenerative medicine, cellular reprogramming, and diseases in which differentiation programs are corrupted.
Park et al. (Tue,) studied this question.