Megakaryocytes regulate hematopoietic stem cell quiescence through CXCL4 secretion

I Bruns, D Lucas, S Pinho, J Ahmed, MP Lambert… - Nature medicine, 2014 - nature.com
I Bruns, D Lucas, S Pinho, J Ahmed, MP Lambert, Y Kunisaki, C Scheiermann, L Schiff
Nature medicine, 2014nature.com
In the bone marrow, hematopoietic stem cells (HSCs) lodge in specialized
microenvironments that tightly control the proliferative state of HSCs to adapt to the varying
needs for replenishment of blood cells while also preventing HSC exhaustion. All putative
niche cells suggested thus far have a nonhematopoietic origin,,,,,,. Thus, it remains unclear
how feedback from mature cells is conveyed to HSCs to adjust their proliferation. Here we
show that megakaryocytes (MKs) can directly regulate HSC pool size in mice. Three …
Abstract
In the bone marrow, hematopoietic stem cells (HSCs) lodge in specialized microenvironments that tightly control the proliferative state of HSCs to adapt to the varying needs for replenishment of blood cells while also preventing HSC exhaustion. All putative niche cells suggested thus far have a nonhematopoietic origin,,,,,,. Thus, it remains unclear how feedback from mature cells is conveyed to HSCs to adjust their proliferation. Here we show that megakaryocytes (MKs) can directly regulate HSC pool size in mice. Three-dimensional whole-mount imaging revealed that endogenous HSCs are frequently located adjacent to MKs in a nonrandom fashion. Selective in vivo depletion of MKs resulted in specific loss of HSC quiescence and led to a marked expansion of functional HSCs. Gene expression analyses revealed that MKs are the source of chemokine C-X-C motif ligand 4 (CXCL4, also named platelet factor 4 or PF4) in the bone marrow, and we found that CXCL4 regulates HSC cell cycle activity. CXCL4 injection into mice resulted in a reduced number of HSCs because of their increased quiescence. By contrast, Cxcl4−/− mice exhibited an increased number of HSCs and increased HSC proliferation. Combined use of whole-mount imaging and computational modeling was highly suggestive of a megakaryocytic niche capable of independently influencing HSC maintenance by regulating quiescence. These results indicate that a terminally differentiated cell type derived from HSCs contributes to the HSC niche, directly regulating HSC behavior.
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