RUNX1-deficient human megakaryocytes demonstrate thrombopoietic, and platelet half-life and functional defects.

Heterozygous defects in runt-related transcription factor-1 (RUNX1) are causative of a familial platelet disorder with associated myeloid malignancy (FPDMM). Since RUNX1-deficient animal models do not mimic FPDMM's bleeding disorder or leukemic risk, establishment of a proper model system is critical to understand the underlying mechanisms of the observed phenotype and to identify therapeutic interventions. We previously reported an in vitro-megakaryopoiesis system using human CD34+-hematopoietic stem and progenitor cells that recapitulated the FPDMM quantitative megakaryocyte defect by decreasing RUNX1 expression using a lentiviral short-hairpin RNA (shRNA for RUNX1 or shRX) strategy. We now show that shRX-megakaryocytes have a marked reduction in agonist responsiveness. We then infused shRX-megakaryocytes into immunocompromised NOD-SCID gamma (NSG) mice and demonstrated that these megakaryocytes released fewer platelets than megakaryocytes transfected with a non-targeting shRNA, and these platelets had a diminished half-life. The platelets were also poorly responsive to agonists, unable to correct thrombus formation in NSG mice homozygous for a R1326H mutation in von Willebrand Factor (VWFR1326H), which switches species-binding specificity of the VWF from mouse to human glycoprotein Iba. A small-molecule inhibitor RepSox, which blocks the transforming-growth factor beta pathway, and which rescued defective megakaryopoiesis in vitro, corrected the thrombopoietic defect, platelet half-life and agonist response, and thrombus formation in NSG/ VWFR1326H mice. Thus, this model recapitulates the defect in FPDMM megakaryocytes and platelets, identifies previously unrecognized defects in thrombopoiesis and platelet half-life, and demonstrates, for the first time, reversal of RUNX1 deficiency's hemostatic defects by a drug.