NGN3 oscillatory expression controls the timing of human pancreatic endocrine differentiation

Understanding protein expression dynamics is crucial for the mechanistic understanding of cell differentiation. We investigate the dynamics and decoding of NGN3, a transcription factor critical for pancreatic endocrine development. A knock-in endogenous reporter shows that NGN3 protein oscillates with a 13-hour periodicity in human iPS-derived endocrine progenitors and is switched off as cells differentiate to ß-like and pre-alpha cells. Increasing NGN3 protein stability results in one broad peak of expression instead of oscillations, with a larger peak to trough fold-change. This leads to precocious endocrine differentiation and earlier expression of key NGN3 target genes. Single-cell analysis of dynamics, mathematical modelling and experimental validation suggest that NGN3 oscillations are decoded by fold-change detection (FCD) rather than the level of expression via an incoherent feedforward loop motif (IFFL) that explains both normal and precocious differentiation. Our findings suggest that oscillatory NGN3 dynamics control the timing of differentiation, but not fate specification. Overall design: We performed gene expression analysis in WT cells every 3 days of the pancreatic differentiation