p53 safeguards chemical reprogramming of human somatic cells toward pluripotency
Summary
Cell fate manipulation is powerful for generating desired cell types through reprogramming. However, reprogramming induces dramatic changes in cell states and identities, which can be risky, necessitating strict regulation to ensure safety and efficiency. p53 is essential for genome stability; however, it functionally opposes oncogenes comprising the Yamanaka factors. Delicately balancing p53 activity for efficient reprogramming has proven challenging. Here, we demonstrate that p53 is esse
Content
# p53 safeguards chemical reprogramming of human somatic cells toward pluripotency
*Published: 2026 Apr 17*
Cell fate manipulation is powerful for generating desired cell types through
reprogramming. However, reprogramming induces dramatic changes in cell states
and identities, which can be risky, necessitating strict regulation to ensure
safety and efficiency. p53 is essential for genome stability; however, it
functionally opposes oncogenes comprising the Yamanaka factors. Delicately
balancing p53 activity for efficient reprogramming has proven challenging. Here,
we demonstrate that p53 is essential for chemical reprogramming, unlike its
inhibitory role in transcription factor-mediated reprogramming. Unexpectedly,
suppressing p53 impairs the generation of chemically induced pluripotent stem
cells (CiPSCs). p53 prevents excessive epithelial-to-mesenchymal transition
during the early reprogramming stages. Retinoic acid signaling activation
promotes CiPSC generation by leveraging p53's anti-metastatic function via BTG2.
Cell proliferation ability is sustained in the presence of p53 expression by
regulating p21 with chemicals. p53 preservation shows practical advantages in
securing genome integrity; thus, chemical reprogramming is promising for
delicately balancing p53 activity and achieving efficient reprogramming for cell
fate manipulation.
DOI: 10.1016/j.cell.2026.03.038