Project description:Purpose: We designed this study to evaluate the feasibility of using only one factor to respecify human induced pluripotent stem cells (iPSCs)-derived blood cells into long-term engraftable hematopoietic stem and progenitor cells (HSPCs). We also parallelly compared iPSC-derived HSPCs (iHSPCs) with primary HSPCs under the same induction and transplantation condition in order to examine the functional equivalency between iHSPCs and bona fide HSPCs. Methods: In vitro derived human iPSC-HSPCs are induced with or without (w/o) doxycycline for the expression of MLL-AF4. In vivo derived bone marrow cells are harvested and FACS-sorted for human populations from primary transplants over nine to sixteen weeks after transplantation. Either iPSC-HSPCs or primary HSPCs, both of which are induced by MLL-AF4, is used for the transplantation experiments. iPSCs are either derived from peripheral blood mobilized CD34+ HSPCs (CD34-iPSC) or mononuclear cells (MN-iPSCs). Normal human CD34+ HSPCs and mononuclear cells are set as control groups. Results: MLL-AF4 can impart HSC and lymphoid potential to iPSC-derived blood cells in vitro, and induction of MLL-AF4 leads to the cellular identity transition from common myeloid progenitors to hematopoietic stem and progenitor cells. MLL-AF4 alone is sufficient to realize the potent engraftment of induced HSPCs (iHSPCs) from iPSCs, and multilineage and long-term hematopoiesis could be observed. Primary HSPCs with the induction of MLL-AF4 could gain significantly enhanced engraftability. During the long-term engraftment period, leukemic mutations with a bias to B-cell leukemia could be found in the iHSPCs and their derivatives. By contrast, MLL-AF4 induced primary HSPCs maintain the normal hematopoiesis without leukemic transformation. Conclusions: Our study has demonstrated for the first time, to our knowledge, that the pluripotency-dependent conversion of somatic cells to long-term engraftable HSPCs can be achieved by using a single factor in a non-integrative way. This study also suggests that iPSC-derived HSPCs are more prone to leukemic mutations during the long-term engraftment period, which provides a necessary caveat of using them in the actual therapies.

Project description:In vitro generation of mature neutrophils from human induced pluripotent stem cells (iPSCs) requires hematopoietic progenitor development followed by myeloid differentiation. The purpose of our studies was to extensively characterize this process, focusing on the critical window of development between hemogenic endothelium, hematopoietic stem/progenitor cells (HSPCs), and myeloid commitment, to identify associated regulators and markers that might enable the stem cell field to improve the efficiency and efficacy of iPSC hematopoiesis. We utilized a 4-stage differentiation protocol involving: embryoid body (EB) formation (Stage-1); EB culture with hematopoietic cytokines (Stage-2); HSPC expansion (Stage-3); and neutrophil maturation (Stage-4). CD34+CD45- putative hemogenic endothelial cells were observed in Stage-3 cultures, and expressed VEGFR-2/Flk-1/KDR and VE-cadherin endothelial markers, GATA-2, AML1/RUNX1, and SCL/TAL1 transcription factors, and endothelial/HSPC-associated microRNAs miR-24, miR-125a-3p, miR-126/126*, and miR-155. Upon further culture, CD34+CD45- cells generated CD34+CD45+ HSPCs that produced hematopoietic CFUs. Mid-Stage-3 CD34+CD45+ HSPCs exhibited increased expression of GATA-2, AML1/RUNX1, SCL/TAL1, C/EBPα, and PU.1 transcription factors, but exhibited decreased expression of HSPC-associated microRNAs, and failed to engraft in immune-deficient mice. Mid-stage-3 CD34-CD45+ cells maintained PU.1 expression and exhibited increased expression of hematopoiesis-associated miR-142-3p/5p and a trend towards increased miR-223 expression, indicating myeloid commitment. By late Stage-4, increased CD15, CD16b, and C/EBPε expression were observed, with 25-65% of cells exhibiting morphology and functions of mature neutrophils. These studies demonstrate that hematopoiesis and neutrophil differentiation from human iPSCs recapitulates many features of embryonic hematopoiesis and neutrophil production in marrow, but reveals unexpected molecular signatures that may serve as a guide for enhancing iPSC hematopoiesis. miRNA expression profiles were analyzed in iNC-01-3 and iNC-01-4 induced pluripotent stem cell lines at day 0 (undifferentiated iPSCs), day 18 of differentiation (embryoid bodies), and in 3 FACS-sorted cell populations at day 22 of differentiation (CD34+CD45- cells, CD34+CD45+ cells, and CD34-CD45+ cells). Comparative CT analysis was normalized to U6 snRNA and RNU48 control RNAs relative to expression in undifferentiated iPSCs. Data includes 2 files for each sample, one for the card A array and one for the card B array. This includes a total of 32 data files consisting of: 5 replicates for undifferentiated iPSCs (10 files), 2 replicates for EB (4 files), 3 replicates for CD34+CD45- (6 files), 3 replicates for CD34+CD45+ (6 files), and 3 replicates for CD34-CD45+ (6 files).

Project description:Osteolineage cell-derived extracellular vesicles (EVs) play a regulatory role in hematopoiesis and have been shown to promote the ex vivo expansion of human hematopoietic stem and progenitor cells (HSPCs). Here, we demonstrate that EVs from different human osteolineage sources do not have the same HSPC expansion promoting potential. Comparison of stimulatory and non-stimulatory osteolineage EVs by next-generation sequencing and mass spectrometry analyses revealed distinct microRNA and protein signatures identifying EV-derived candidate regulators of ex vivo HSPC expansion. Accordingly, the treatment of umbilical cord blood-derived CD34+ HSPCs with stimulatory EVs altered HSPC transcriptome, including genes with known roles in cell proliferation. An integrative bioinformatics approach, which connects the HSPC gene expression data with the candidate cargo in stimulatory EVs, delineated the potentially targeted biological functions and pathways during hematopoietic cell expansion and development. In conclusion, our study gives novel insights into the complex biological role of EVs in osteolineage cell-HSPC crosstalk and promotes the utility of EVs and their cargo as therapeutic agents in regenerative medicine.

Project description:Global mechanisms defining the gene expression programs specific for hematopoiesis are still not fully understood. Here, we show that promoter DNA demethylation is associated the activation of hematopoietic-specific genes. Using genome-wide promoter methylation arrays, we identified 694 hematopoietic-specific genes repressed by promoter DNA methylation in human ESCs and whose loss of methylation in hematopoietic can be associated with gene expression. The association between promoter methylation and gene expression was studied for many hematopoietic-specific genes including CD45, CD34, CD28, CD19, the T cell receptor (TCR), the MHC class II gene HLA-DR, perforin 1, and the phosphoinositide 3-kinase (PI3K) and results indicated that DNA demethylation was not always sufficient for gene activation. Promoter demethylation occurred either early during embryonic development or later on during hematopoietic differentiation. Analysis of the genome-wide promoter methylation status of induced pluripotent stem cells (iPSCs) generated from somatic CD34+ HSPCs and differentiated derivatives from CD34+ HSPCs confirmed the role of DNA methylation in regulating the expression of genes of the hemato-immune system, and indicated that promoter methylation of these genes may be associated to stemness. Together, these data suggest that promoter DNA demethylation might play a role in the tissue/cell-specific genome-wide gene regulation within the hematopoietic compartment. Total DNA isolated by standard procedures from different primary samples corresponding to healthy patients and several cell lines.

Project description:Hematopoietic cell fate decisions such as self-renewal and differentiation are highly regulated through multiple molecular pathways. One pathway, the ubiquitin proteasome system (UPS), controls protein levels by tagging them with polyubiquitin chains and promoting their degradation through the proteasome. Ubiquitin E3 ligases serve as the substrate-recognition component of the UPS. Through investigating the FBOX family of E3 ligases, we discovered that Fbxo21 was highly expressed in the hematopoietic stem and progenitor cell (HSPC) population, and showed low to no expression in mature myeloid populations. To determine the role of FBXO21 on HSPC maintenance, self-renewal, and differentiation, we generated shRNAs against FBXO21 and a hematopoietic specific Fbxo21 conditional knockout (cKO) mouse model. We found that silencing FBXO21 in HSPCs led to a loss in colony formation and an increase in cell differentiation in vitro. Additionally, stressing the HSPC populations in our Fbxo21 cKO mouse with 5-FU injections resulted in a decrease in survival, despite these populations showing minimal alterations during steady-state hematopoiesis. Although FBXO21 has previously been proposed to regulate cytokine signaling via ASK and p38, our results show that depletion of FBXO21 led to altered ERK signaling in vitro. Together, these findings suggest ubiquitin E3 ligase FBXO21 regulates HSPCs through cytokine mediated pathways.

Project description:In vitro generation of mature neutrophils from human induced pluripotent stem cells (iPSCs) requires hematopoietic progenitor development followed by myeloid differentiation. The purpose of our studies was to extensively characterize this process, focusing on the critical window of development between hemogenic endothelium, hematopoietic stem/progenitor cells (HSPCs), and myeloid commitment, to identify associated regulators and markers that might enable the stem cell field to improve the efficiency and efficacy of iPSC hematopoiesis. We utilized a 4-stage differentiation protocol involving: embryoid body (EB) formation (Stage-1); EB culture with hematopoietic cytokines (Stage-2); HSPC expansion (Stage-3); and neutrophil maturation (Stage-4). CD34+CD45- putative hemogenic endothelial cells were observed in Stage-3 cultures, and expressed VEGFR-2/Flk-1/KDR and VE-cadherin endothelial markers, GATA-2, AML1/RUNX1, and SCL/TAL1 transcription factors, and endothelial/HSPC-associated microRNAs miR-24, miR-125a-3p, miR-126/126*, and miR-155. Upon further culture, CD34+CD45- cells generated CD34+CD45+ HSPCs that produced hematopoietic CFUs. Mid-Stage-3 CD34+CD45+ HSPCs exhibited increased expression of GATA-2, AML1/RUNX1, SCL/TAL1, C/EBPα, and PU.1 transcription factors, but exhibited decreased expression of HSPC-associated microRNAs, and failed to engraft in immune-deficient mice. Mid-stage-3 CD34-CD45+ cells maintained PU.1 expression and exhibited increased expression of hematopoiesis-associated miR-142-3p/5p and a trend towards increased miR-223 expression, indicating myeloid commitment. By late Stage-4, increased CD15, CD16b, and C/EBPε expression were observed, with 25-65% of cells exhibiting morphology and functions of mature neutrophils. These studies demonstrate that hematopoiesis and neutrophil differentiation from human iPSCs recapitulates many features of embryonic hematopoiesis and neutrophil production in marrow, but reveals unexpected molecular signatures that may serve as a guide for enhancing iPSC hematopoiesis.

Project description:Severe congenital neutropenia (CN) is a pre-leukemia syndrome that, in the majority of patients, is caused by heterogeneous ELANE mutations encoding neutrophil elastase (NE). To study leukemogenesis associated with CN we generated CN and CN/AML patient-specific induced pluripotent stem cells (iPSCs). Additional mutations in leukemia-relevant genes, CSF3R and RUNX1, were introduced using CRISPR/Cas9 gene-editing. Consequently, we performed in vitro embryoid body (EB)-based hematopoietic and myeloid differentiation of generated iPSC lines. On day 14-17 of EB-based differentiation, iPSC-derived CD45+CD34+ cells were harvested and mRNA was isolated using RNeasy Mini- or Micro Kit (Qiagen). Sequencing libraries were prepared using the TruSeq RNA Sample Prep Kit (Illumina). Poly (A) selected single-read and pair-read sequencing libraries were sequenced on the Illumina platform in order to compare the transcriptomes of CN and CN/AML iPSCs-derived HSPCs from 2 CN/AML patients. Next, we identified that BAALC knockout resulted in a dramatic induction of granulocytic differentiation and a significant reduction in proliferation of CN/AML iPSC-derived HSPCs. To identify BAALC-dependent leukemia-associated gene expression, we compared the transcriptomes of CN/AML iPSCs before and after BAALC KO using a similar approach described above for CN and CN/AML iPSCs-derived HSPCs.

Project description:Erythropoiesis is a crucial part in hematopoietic system, while facing disruptions from various diseases conditions. Anemia and blood shortages has become global challenges, with current finite pharmacological options like EPO or glucocorticoids having limitations, especially in genetic anemias like Diamond-Blackfan anemia (DBA), calling for novel candidates in stimulating the erythropoiesis. We designed the primary human hematopoietic stem and progenitor cells (HSPCs) chemicals screening system in erythropoiesis and unexpectedly discovered a BRAF inhibitor, effectively against BRAFV600E mutant cancers, delaying erythroid differentiation while promoting progenitors’ proliferation. Further research demonstrated its efficacy in cytokine-restricted conditions and in samples from erythroid disorder patients. Mechanistically, BRAF inhibitors paradoxically activated the RAF-MEK-ERK/MAPK pathway. Unlike oncogenic BRAFV600E impaired hematopoiesis and erythropoiesis via AP-1 hyperactivation, BRAF inhibitors minimally affected HSPCs self-renewal and differentiation. In vivo studies further exhibited BRAF inhibitors' potential to enhance human hematopoiesis and erythropoiesis in severe immunodeficient mouse models and alleviate anemia symptoms in Rpl11 haploinsufficiency DBA models and other anemia models. This discovery sheds light on the MAPK pathway's role in hematopoiesis, making BRAF inhibitors a novel clinically therapeutic choice in improving hematopoietic reconstitution and the recovery of anemias like DBA.

Project description:Fanconi anemia (FA) is a genetic disorder of DNA repair that manifests as bone marrow dysfunction typically occurring in childhood. The lack of human model systems has impeded progress in identifying effective therapies. To address this, efforts have focused on using directed differentiation of patient-derived human induced pluripotent stem cells (IPSCs) to hematopoietic stem and progenitor cells (HSPCs). However, the requirement for an intact FA DNA repair pathway for efficient reprogramming of patient cells to pluripotency requires genetic complementation of FA pathway defects to efficiently generate IPSCs, precluding derivation of FA pathway-deficient human HSPCs for study. To overcome this barrier, we employed a system of doxycycline-inducible complementation of FANCA deficient patient-derived IPS cells. Doxycycline exposure allowed for the robust maintenance of undifferentiated IPS cells in culture. Removal or retention of doxycycline exposure during directed differentiation of HSPCs allowed for the production of isogenic FANCA-deficient and FANCA-complemented human HSPCs. IPS-derived, FANCA-deficient HSPCs showed impaired response to genotoxic stress, proliferation, and survival compared to complemented HSPCs. Using these cells, we found that FANCA-deficient HSPCs showed expected impaired clonogenicity in methylcellulose culture and unexpected accelerated erythroid differentiation relative to complemented cells. Activation of p53-mediated p21 transactivation in FANCA-deficient HSPCs serves to drive accelerated erythropoiesis as the expense of clonogenicity. This study demonstrates the feasibility of inducible complementation in IPSCs as a method to generate isogenic FA-deficient and FA-complemented human HPSCs for disease modeling and uncovers a novel mechanism by which the FA pathway regulates the balance between stem cell maintenance and terminal differentiation.

Project description:The variation among induced pluripotent stem cells (iPSCs) in their differentiation capacity to specific lineages is frequently attributed to somatic memory. In this study, we compared hematopoietic differentiation capacity of 35 human iPSC lines derived from four different tissues and four embryonic stem cell lines. The analysis revealed that hematopoietic commitment capacity (PSCs to hematopoietic precursors) is correlated with the expression level of the IGF2 gene independent of the iPSC origins. In contrast, maturation capacity (hematopoietic precursors to mature blood) is affected by iPSC origin; blood-derived iPSCs showed the highest capacity. However, some fibroblast-derived iPSCs showed higher capacity than blood-derived clones. Tracking of DNA methylation changes during reprogramming reveals that maturation capacity is highly associated with aberrant DNA methylation acquired during reprogramming, rather than the types of iPSC origins. These data demonstrated that variations in the hematopoietic differentiation capacity of iPSCs are not attributable to somatic memories of their origins. Human iPSCs after hematopoietic differentiation (n = 2), human iPSCs after neural differentiation (n = 1), human iPSCs with different culture conditions (n = 8), and human iPSC line forced to express IGF2 gene (n = 1), and its control (n = 1).