Congenital heart disease is the most common congenital anomaly, affecting approximately 1% of all live births each year. Although clinical interventions are improving, many affected infants do not survive to adulthood. Congenital cardiac defects originate from disturbances during development, making the study of mammalian cardiogenesis critical to improving outcomes for infants with congenital heart disease. Development of the mammalian heart involves epigenetically-driven specification and commitment of a diverse landscape of cardiac progenitors. Recent studies determined that chromatin modifying enzymes play a previously underappreciated role in the pathogenesis of congenital heart defects. This thesis investigates the functions of Hdac1 and Hdac2, highly homologous Class I histone deacetylases, during early murine cardiac development. We establish that Hdac1 and Hdac2 cooperatively regulate cardiogenesis in distinct cardiac progenitor populations during development. Together, our findings demonstrate that Hdac1 and Hdac2 are critical mediators of the earliest stages of mammalian cardiogenesis through a variety of spatiotemporally specific, redundant, and dose-sensitive roles and indicate they may play important roles in the pathogenesis of human congenital cardiac defects.

Disruptions in cardiac development cause congenital heart disease, the most prevalent and deadly congenital malformation. Genetic and environmental factors are thought to contribute to these defects, however molecular mechanisms remain largely undefined. Recent work highlighted potential roles of chromatin- modifying enzymes in congenital heart disease pathogenesis. Histone deacetylases, a class of chromatin-modifying enzymes, have developmental importance and recognized roles in the mature heart. This thesis aimed to characterize functions of Hdac3 in cardiac development. We found loss of Hdac3 in the primary heart field causes precocious progenitor cell differentiation, resulting in hypoplastic ventricular walls, ventricular septal defect, and mid- gestational lethality. In primary heart field progenitors, Hdac3 interacts with, deacetylates, and functionally suppresses transcription factor Tbx5. Furthermore, a disease-associated Tbx5 mutation disrupts this interaction, rendering Tbx5 hyperacetylated and hyperactive. By contrast, deletion of Hdac3 in second heart field progenitors bypasses these defects, instead causing malformations in the outflow tract and semilunar valves, with lethality prior to birth. Affected semilunar valves and outflow tract vessels exhibit extracellular matrix and EndMT defects and activation of the Tgfβ1 signaling pathway. In normal second heart field development, Hdac3 represses Tgfβ1 transcription, independent of its deacetylase activity, by recruiting the PRC2 methyltransferase complex to methylate the Tgfβ1 promoter. Importantly, knockouts of Hdac3 in differentiated cardiac cells do not fully recapitulate the progenitor-specific knockout phenotypes. These results illustrate spatiotemporal roles of Hdac3, both deacetylase-dependent and deacetylase-independent, in cardiac development, suggesting that dysregulation of Hdac3 in cardiac progenitor cells could be a contributing factor in congenital heart disease pathogenesis.