During hematopoiesis, lineage-and stage-specific transcription factors work in concert with chromatin modifiers to direct the differentiation of all blood cells. Here, we explored the role of KRAB-containing zinc finger proteins (KRAB-ZFPs) and their cofactor KAP1 in this process. Hematopoietic-restricted deletion of Kap1 in the mouse resulted in severe hypoproliferative anemia. Kap1-deleted erythroblasts failed to induce mitophagy-associated genes and retained mitochondria. This was due to persistent expression of microRNAs targeting mitophagy transcripts, itself secondary to a lack of repression by stage-specific KRAB-ZFPs. The KRAB/ KAP1-miRNA regulatory cascade is evolutionary conserved, as it also controls mitophagy during human erythropoiesis. Thus, a multilayered transcription regulatory system is present, where protein-and RNA-based repressors are super-imposed in combinatorial fashion to govern the timely triggering of an important differentiation event.Through the process of erythropoiesis, about one hundred billion new red cells are generated every day in the human adult bone marrow. This process is initiated by the differentiation of hematopoietic stem cells (HSC) into the earliest erythroid progenitor, which was identified ex vivo as a slowly growing burst-forming unit-erythroid (BFU-E). This erythroid progenitor morphs into the rapidly dividing CFU-E (colony-forming unit-erythroid), the proliferation of which is stimulated by the hypoxia-induced hormone erythropoietin. Further differentiation occurs through a highly sophisticated program orchestrated by lineage-and stage-specific combinations of protein-and RNA-based transcription regulators (1-3). It culminates in the elimination of intracellular organelles including mitochondria and the nucleus to yield the fully mature erythrocyte, containing on the order of 250 million molecules of hemoglobin as almost sole cargo. Much is still to be learned about the molecular mechanisms of these events, not only to understand the cause of red cell disorders, but also to aid the in vitro manufacturing of the large supplies of oxygen-carrying cells for transfusion.Higher vertebrate genomes encode hundreds of KRAB-ZFPs that can bind DNA in a sequence-specific fashion through a C-terminal array of C2H2 zinc fingers and recruit the ‡ Corresponding author. didier.trono@epfl.ch.
Tag-lite et Richard Miller (Chicago)
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