TBX5 dosage governs ventricular cardiomyocyte maturation, specialization and dedifferentiation in vivo

Variation in transcription factor (TF) activity modulates traits and disease susceptibility, yet how such variation translates into cellular phenotype and organ function in vivo is not well established. We utilized AAV-mediated gene delivery to express the dosage-sensitive TF TBX5 across a physiologically plausible range in postnatal ventricular cardiomyocytes. Transcriptomic profiling revealed that TBX5 dosage-dependent cardiomyocyte states changed gradually and often non-monotonically across the TBX5 dosage spectrum. The lowest dosages induced cardiomyocyte hypertrophy and upregulated gene programs governing oxidative metabolism, calcium handling, and contractility. In contrast, mid-to-high dosages induced a ventricular conduction system-like transcriptional profile. Supraphysiological dosages triggered cardiomyocyte dedifferentiation, characterized by cardiomyocyte size reduction, cell cycle re-entry, metabolic reprogramming, and impaired ventricular ejection fraction. Furthermore, the ventricular state of an Nppa-Nppb deficiency model characterized by cardiac hypertrophy and reduced Tbx5 expression was partially normalized by TBX5 delivery. By defining the non-linear relationship of TBX5 activity level, cardiomyocyte state and cardiac function, our study reveals how TF dosage regulates the transitions from physiological maturation to specialized lineage acquisition and dedifferentiation at the cell and organ level in vivo .