In this issue of Blood, Wei et al describe how the nuclear corepressor ncor2 helps keep hemogenic gene expression at just the right level necessary for hematopoietic stem and progenitor cell (HSPC) emergence.1 Forming an HSPC requires a Goldilocks touch in that too much or too little signal can inhibit their formation from specialized hemogenic endothelial cells. These results shed light on a critical factor in establishing proper balance during HSPC formation.
HSPCs emerge from endothelial cells within the dorsal aorta. Disruptions in endothelial or arterial identity lead to defects in HSPC formation. The nuclear corepressor, ncor2, acts as a gatekeeper of vascular and hemogenic endothelial fate through its regulation of c-fos, vegfd, and Notch signaling.
HSPCs emerge from endothelial cells within the dorsal aorta. Disruptions in endothelial or arterial identity lead to defects in HSPC formation. The nuclear corepressor, ncor2, acts as a gatekeeper of vascular and hemogenic endothelial fate through its regulation of c-fos, vegfd, and Notch signaling.
Derivation of bona fide HSPCs from pluripotent stem cells could provide a new source of hematopoietic cells for patients in need of bone marrow transplantation, but current protocols for directed differentiation generally produce embryonic blood cells and fail to generate engraftable, definitive HSPCs. During development, HSPCs are born from a subset of endothelial cells within the dorsal aorta (see figure). Hemogenic endothelium induction is a necessary intermediate step for definitive hematopoietic cell generation, yet the transcriptional events needed to specify hemogenic from vasculature endothelium are largely unknown. Two recent studies aimed at direct reprogramming of nonhematopoietic cells to HSPCs demonstrate that Fos is one factor involved in promoting hemogenic endothelium induction.2,3 The current study in Blood now sheds light on the endogenous regulation of c-fos during the in vivo endothelial-to-hematopoietic transition and provides insight into other factors important for the conversion.
The nuclear corepressor ncor2 is highly expressed in the dorsal aorta of developing zebrafish at a time in the development when hemogenic endothelium induction occurs. Using genetic approaches in zebrafish, Wei et al define ncor2 and its corepressor, the histone deacetylase hdac3, as essential components for HSPC production. This complex normally represses expression of genes; thus, upon knockdown several transcripts are increased, such as c-fos (FBJ murine osteosarcoma viral oncogene homolog) and vascular endothelial growth factor-D (vegfd). Genetic epistasis experiments showed that vegfd is downstream of c-fos, which is downstream of ncor2 and hdac3 during HSPC formation. Interestingly, a dose escalation study showed that low-level overexpression of c-fos actually enhanced HSPC production consistent with the reprogramming studies, whereas high-level overexpression was inhibitory. Endothelial overexpression of c-fos further demonstrated that there is an optimal level of c-fos needed to promote hemogenic endothelium formation in a cell autonomous manner. One question arising from these studies is “What is the fate of the endothelial cells that no longer turn into blood?” The authors provide data showing an increase in expression of the arterial markers ephrinb2 and dll4 (δ-like protein 4), both targets of the Notch signaling pathway. These data imply that ncor2 normally suppresses Notch activity. Consistent with this finding, chemical inhibition of Notch signaling with DAPT restores HSPC levels in ncor2 knockdown embryos, as well as when c-fos or vegfd is overexpressed. Previous studies in mouse and chick also found that sustained and inappropriate Notch activity diminished blood production from the dorsal aorta.4,5 Together, these data suggest that when Notch signaling is imbalanced, hemogenic endothelium will likely remain arterial endothelium.
While this study is a clear step forward in our understanding of hemogenic endothelium induction, many questions remain. ncor2 is expressed throughout the aorta and controls expression of arterial markers throughout the vessel, yet loss of ncor2 only affects hemogenic endothelial formation. What other factors restrict the function of ncor2 within the presumptive hemogenic endothelial cells? Does ncor2 regulate expression of c-fos, vegfd, or Notch targets directly by binding to cell-type specific regulatory elements within these genes? How does ncor2, c-fos, or vegfd alter Notch signaling? vegfd is a prolymphangiogenic molecule, so could the effects observed with vegfd overexpression result from changes to lymphatic vessel formation? Are lymphatic vessel formation and HSPC emergence coordinated? Although lymphatic endothelial cells are derived from venous endothelial cells6 and not arterial cells, there is evidence that lymphangiogenic factors might have a supportive role for hematopoietic progenitors during development.7 Could these endothelial fate changes alter the HSPC niche? The work from Wei et al provides novel insight into the delicate balance of endothelial and hematopoietic fate choices during development, offering new directions in the quest to generate functional blood stem cells in vitro for transplantation therapies.
Conflict-of-interest disclosure: The author declares no competing financial interests.
