Abstract

Background: Early human heart and brain development simultaneously occur during embryogenesis. Notably, in human newborns, congenital heart defects strongly associate with neurodevelopmental abnormalities, suggesting a common gene/complex underlying both cardiogenesis and neurogenesis. However, due to lack of in vivo studies, the molecular mechanisms that govern both early human heart and brain development remain elusive. The evolutionarily conserved ATP-dependent SWI/SNF complex is one of the largest chromatin remodeling complexes, consisting of ~15 subunits, including SMARCA2 (also known as BRM) or SMARCA4 (also known as BRG1) as the ATPase catalytic subunit. Several BRG1-associated factors (BAFs), such as ARID1A (Baf250a), have DNA binding capacity and assemble with either BRM or BRG1 to form a functional chromatin-remodeling complex. A single amino acid mutation (Arid1aV 1068G/V1068G ), impaired Arid1a-DNA interactions and resulted in both cardiac neural defects. Mutations in 4 different SWI/SNF subunits including ARID1A/B were identified in human congenital syndromes that include both neural and cardiac defects. Results: Here, we report ARID1A, which is a DNA-binding-subunit of the SWI/SNF epigenetic complex, controls both neurogenesis and cardiogenesis from human embryonic stem cells (hESCs) via employing distinct mechanisms. CRISPR/Cas-9 knockout of ARID1A (ARID1A -/- ) led to spontaneous differentiation of neural cells together with globally enhanced expression of neurogenic genes in undifferentiated hESCs. Additionally, when compared with WT hESCs, cardiac differentiation from ARID1A -/- hESCs was prominently suppressed, whereas neural differentiation was significantly promoted. Whole genome-wide ChIP-seq and ATAC-seq analyses revealed that ARID1A was required to open chromatin accessibility on promoters of essential cardiogenic genes, and temporally associated with key cardiogenic transcriptional factors T and MEF2C during early cardiac development. However, during neural development, transcription of most essential neurogenic genes was dependent on ARID1A and ARID1A could interact with REST, which is a known transcriptional repressor. Conclusions: We uncovered the key and opposite roles by ARID1A to govern both early human cardiac and neural development and characterized the mechanisms. We found global chromatin accessibility on cardiogenic genes was dependent on ARID1A, whereas transcriptional activity of neurogenic genes was regulated by ARID1A, possibly through ARID1A-REST interaction.

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