Number of megakaryocytic progenitors and adhesion molecule expression of stem cells predict platelet engraftment after allogeneic hematopoietic stem cell transplantation

Human NOTCH4 is a key target of RUNX1 in megakaryocytic differentiation

Megakaryocytes (MKs) in adult marrow produce platelets that play important roles in blood coagulation and hemostasis. Monoallelic mutations of the master transcription factor gene RUNX1 lead to familial platelet disorder (FPD) characterized by defective MK and platelet development. However, the molecular mechanisms of FPD remain unclear. Previously, we generated human induced pluripotent stem cells (iPSCs) from patients with FPD containing a RUNX1 nonsense mutation. Production of MKs from the FPD-iPSCs was reduced, and targeted correction of the RUNX1 mutation restored MK production. In this study, we used isogenic pairs of FPD-iPSCs and the MK differentiation system to identify RUNX1 target genes. Using integrative genomic analysis of hematopoietic progenitor cells generated from FPD-iPSCs, and mutation-corrected isogenic controls, we identified 2 gene sets the transcription of which is either up- or downregulated by RUNX1 in mutation-corrected iPSCs. Notably, NOTCH4 expression was negatively controlled by RUNX1 via a novel regulatory DNA element within the locus, and we examined its involvement in MK generation. Specific inactivation of NOTCH4 by an improved CRISPR-Cas9 system in human iPSCs enhanced megakaryopoiesis. Moreover, small molecules known to inhibit Notch signaling promoted MK generation from both normal human iPSCs and postnatal CD34+ hematopoietic stem and progenitor cells. Our study newly identified NOTCH4 as a RUNX1 target gene and revealed a previously unappreciated role of NOTCH4 signaling in promoting human megakaryopoiesis. Our work suggests that human iPSCs with monogenic mutations have the potential to serve as an invaluable resource for discovery of novel druggable targets.

Safety and Efficacy of Megakaryocytes Induced from Hematopoietic Stem Cells in Murine and Nonhuman Primate Models

Because of a lack of platelet supply and a U.S. Food and Drug Administration‐approved platelet growth factor, megakaryocytes have emerged as an effective substitute for alleviating thrombocytopenia. Here, we report the development of an efficient two‐stage culture system that is free of stroma, animal components, and genetic manipulations for the production of functional megakaryocytes from hematopoietic stem cells. Safety and functional studies were performed in murine and nonhuman primate models. One human cryopreserved cord blood CD34⁺ cell could be induced ex vivo to produce up to 1.0 × 10⁴ megakaryocytes that included CD41a⁺ and CD42b⁺ cells at 82.4% ± 6.1% and 73.3% ± 8.5% (mean ± SD), respectively, yielding approximately 650‐fold higher cell numbers than reported previously. Induced human megakaryocytic cells were capable of engrafting and producing functional platelets in the murine xenotransplantation model. In the nonhuman primate model, transplantation of primate megakaryocytic progenitors increased platelet count nadir and enhanced hemostatic function with no adverse effects. In addition, primate platelets were released in vivo as early as 3 hours after transplantation with autologous or allogeneic mature megakaryocytes and lasted for more than 48 hours. These results strongly suggest that large‐scale induction of functional megakaryocytic cells is applicable for treating thrombocytopenic blood diseases in the clinic. Stem Cells Translational Medicine2017;6:897–909

A hyperactive Mpl-based cell growth switch drives macrophage-associated erythropoiesis through an erythroid-megakaryocytic precursor

Several approaches for controlling hematopoietic stem and progenitor cell expansion, lineage commitment, and maturation have been investigated for improving clinical interventions. We report here that amino acid substitutions in a thrombopoietin receptor (Mpl)--containing cell growth switch (CGS) extending receptor stability improve the expansion capacity of human cord blood CD34(+) cells in the absence of exogenous cytokines. Activation of this CGS with a chemical inducer of dimerization (CID) expands total cells 99-fold, erythrocytes 70-fold, megakaryocytes 0.5-fold, and CD34(+) stem/progenitor cells 4.4-fold by 21 days of culture. Analysis of cells in these expanded populations identified a CID-dependent bipotent erythrocyte-megakaryocyte precursor (PEM) population, and a CID-independent macrophage population. The CD235a(+)/CD41a(+) PEM population constitutes up to 13% of the expansion cultures, can differentiate into erythrocytes or megakaryocytes, exhibits very little expansion capacity, and exists at very low levels in unexpanded cord blood. The CD206(+) macrophage population constitutes up to 15% of the expansion cultures, exhibits high-expansion capacity, and is physically associated with differentiating erythroblasts. Taken together, these studies describe a fundamental enhancement of the CGS expansion platform, identify a novel precursor population in the erythroid/megakaryocytic differentiation pathway of humans, and implicate an erythropoietin-independent, macrophage-associated pathway supporting terminal erythropoiesis in this expansion system.

The systematic production of cells for cell therapies. Cell Stem Cell. 2008;3:369-381. [PMID: 18940729 DOI: 10.1016/j.stem.2008.09.001]

Stem cells have emerged as the starting material of choice for bioprocesses to produce cells and tissues to treat degenerative, genetic, and immunological disease. Translating the biological properties and potential of stem cells into therapies will require overcoming significant cell-manufacturing and regulatory challenges. Bioprocess engineering fundamentals, including bioreactor design and process control, need to be combined with cellular systems biology principles to guide the development of next-generation technologies capable of producing cell-based products in a safe, robust, and cost-effective manner. The step-wise implementation of these bioengineering strategies will enhance cell therapy product quality and safety, expediting clinical development.

Hematopoietic engraftment of dimethyl sulfoxide-depleted autologous peripheral blood progenitor cells

BACKGROUND

Autologous stem cell transplantation with cryopreserved autografts is a prerequisite for high-dose chemotherapy in treatment of several malignancies. Adverse effects due to the cryoprotectant dimethyl sulfoxide (DMSO) vary from mild to severe. DMSO-associated adverse effects can be reduced by DMSO depletion before autograft infusion. The aim was to investigate whether DMSO depletion by manual single wash reduced frequency of adverse effects or had detrimental effects on the engraftment potential of peripheral blood progenitor cell (PBPC) autografts.

STUDY DESIGN AND METHODS

Ten percent DMSO was used to cryopreserve PBPC autografts for a total of 53 patients with multiple myeloma (n = 41), non-Hodgkin's lymphoma (n = 8), amyloidosis (n = 3), and polyneuropathy, organomegaly, endocrinopathy, M protein, and skin changes (POEMS) syndrome (n = 1). After high-dose chemotherapy, 34 patients received unmanipulated autografts, whereas for 19 patients the autografts were manually washed before stem cell infusion. Adverse effects after the infusion as well as neutrophil (neutrophil count >0.5 x 10(9)/L) and platelet (PLT) engraftment (PLT count >20 x 10(9)/L) for these two groups were compared.

RESULTS

DMSO depletion reduced the frequency of adverse effects significantly. Patients transplanted with DMSO-depleted autografts had similar neutrophil engraftment time as patients receiving unmanipulated autografts. PLT engraftment time, however, was significantly prolonged and PLT transfusion requirements significantly increased for patients receiving DMSO-depleted autografts, even though the numbers of infused CD34+ cells per kg did not differ between the groups.

CONCLUSIONS

DMSO depletion through a manual single wash is a time-consuming procedure that reduces adverse effects. Although the procedure leads to an increase of 2 days in PLT engraftment time, it can be recommended for selected patients with high risk of serious DMSO toxicity.