The DNA-binding protein ARID3a is Required for Human Erythrocyte Lineage Differentiation using the K562 Model Cell Line

Abstract

Abstract Our previous studies demonstrated that AT-rich interacting domain 3a (ARID3a), a DNA-binding protein associated with increased immunoglobulin heavy chain transcription and chromatin accessibility, is required for normal hematopoiesis in mice and in human cells. ARID3a knockout mice exhibited low numbers of erythrocytes and died due to failed erythropoiesis between days 9 and 12 of gestation. The role of ARID3a in human erythropoiesis has not been studied. Stimulation of the human K562 cell line with hemin induces fetal globin synthesis and erythrocyte differentiation. K562 cells constitutively express ARID3a, so we used this cell line to determine if ARID3a is important for human erythrocyte differentiation. Knockdown of ARID3a with shRNA in hemin-stimulated K562 cells resulted in >75% inhibition of globin. To identify genes affected by ARID3a loss, we performed RNA-seq experiments at various times after hemin stimulation with and without ARID3a. ARID3a shRNA-inhibited cells confirmed inhibition of globin gene products, including HBA1, HBA2, and HBZ. Erythroid specific transcription factors were also inhibited in samples treated with ARID3a shRNA while myeloid surface markers were induced. Several critical upstream regulators of ARID3a were also identified in these analyses. These data suggest that ARID3a is important for cell fate decisions in erythropoiesis in human cells and identifies potential important targets of ARID3a in this process.