Differential requirements for different subfamilies of the mammalian SWI/SNF chromatin remodeling enzymes in myoblast differentiation

Abstract

AbstractMammalian SWI/SNF (mSWI/SNF) complexes are ATP-dependent chromatin remodeling enzymes that are critical for normal cellular functions and that are mis-regulated in ∼20% of human cancers. These enzymes exhibit significant diversity in the composition of individual enzyme complexes. mSWI/SNF enzymes are classified into three general sub-families based on the presence or absence of specific subunit proteins. The three sub-families are called BAF (BRM or BRG1-associated factors), ncBAF (non-canonical BAF), and PBAF (Polybromo-associated BAF). The biological roles for the different subfamilies of mSWI/SNF enzymes are poorly described. We knocked down (KD) the expression of genes encoding subunit proteins unique to each of the three subfamilies,Baf250A, Brd9, andBaf180, which mark the BAF, ncBAF, and PBAF sub-families, respectively, and examined the requirement for each in myoblast differentiation. We found that BAF250A and the BAF complex was required to drive lineage-specific gene expression during myoblast differentiation. KD ofBaf250Areduced the expression of the lineage determinantMyogeninand other differentiation markers, due to decreased binding of BAF250A to myogenic gene promoters. KD ofBrd9delayed myoblast differentiation. However, RNA-seq analysis revealed that while theBaf250A-dependent gene expression profile included genes involved in myogenesis, theBrd9-dependent gene expression profile did not. Moreover, no-colocalization of Baf250A and Brd9 was observed in differentiating cells, suggesting independent mechanisms of action for BAF and ncBAF complexes in myogenesis. The PBAF complex was dispensable for myoblast differentiation. The results distinguish between the roles of the mSWI/SNF enzyme subfamilies during myoblast differentiation.