Project description:The shortage of platelets is becoming increasingly prominent owing to their short shelf life, limited supply, and increasing demand in response to public health incidents. It is an attractive idea to obtain large numbers of transfusible megakaryocytes (MKs) and platelets from somatic cells via cell lineage reprogramming. However, generating human MKs from somatic cells using a pharmacological reprogramming approach has not been widely explored. Here, we report the successful generation of human induced MKs (iMKs) from cord blood erythroblasts (EBs) using a chemical reprogramming strategy with a combination of four small molecules (4M): Bix01294, RG108, VPA, and PD0325901. The iMKs exhibited the ability to produce proplatelets and release vital functional platelets in vitro, demonstrating their similarity to natural MKs. Importantly, after injection into mice, iMKs were able to mature and give rise to functional platelets that were incorporated into newly formed thrombi. The reprogramming process was carefully examined using single-cell RNA sequencing, which revealed an efficient, rapid, and successful cell fate conversion of EBs to iMKs by 4M via the intermediate state of bipotent precursors. Assay for transposase-accessible chromatin sequencing results indicated that 4M induced genome-wide chromatin remodeling during MK reprogramming from EBs. 4M drove the transition of the transcription factor gene network by downregulating the key erythroid transcription factor genes KLF1 and MYB and subsequently upregulating MK development-associated transcription factor genes, including FLI1 and MEIS1. This process eventually led human cord blood EBs to acquire the MK fate. Thus, our chemical reprogramming of cord blood EBs to iMKs provides a simple and efficient approach to generating clinically transfusible MKs and platelets.

Project description:Human embryonic stem cells (hESCs) have become an ideal cell source for the ex vivo generation of megakaryocyte (MK) and platelet products for clinical applications. However, an ongoing challenge is to establish scalable culture systems to maximize the yield of stem cell-derived MKs that release platelets. We defined a specific dynamic 3D manufacturing system that could remarkably facilitate megakaryopoiesis and increase the yield of platelet-producing MKs from hESCs within a 12-day induction period. Additionally, an increased number of > 16N ploidy MKs, proplatelets, and platelets were generated from induced cells harvested on day 12 using the specific dynamic culture method. The specific dynamic culture method significantly enhanced endothelium-to-hematopoietic transition and early hematopoiesis. More importantly, MK fate was significantly facilitated in a specific dynamic manner during early hematopoiesis. Mechanistically, this dynamic culture significantly enhanced mitochondrial function via the oxidative phosphorylation pathway and caused differentiation skewing of hESCs toward megakaryopoiesis. We defined a specific dynamic culture system in a baffled-flow manner that enabled the mass production of MKs from hESCs within 12 days. This study can aid in the automatic and scalable production of MKs from stem cells using baffled-flow bioreactors and assist in the manufacturing of hESC-derived MK and platelet products.

Project description:Platelets are anucleated blood cells that are produced by their progenitor cell, the megakaryocyte (MK). Platelets are centrally positioned in hemostasis and thrombosis and, according to the recent findings, play key roles in innate immunity, inflammation, atherogenesis, and cancer metastasis. The quantitative and qualitative properties of platelets are crucial determinants of their hemostatic function. While the regulatory mechanisms of platelet number and size have been studied separately, critical questions remain regarding the interplay of platelet number and size in hemostasis. In this study, using a mouse model of irradiation (IR)-induced thrombocytopenia, we show that mature MKs (mMKs) are resistant to IR and maintain the nadir platelet levels post IR. To identify the phenotype switching and function variation in BM MKs post IR, we performed microarray expression profiling of MKs from the bone marrow of mice at 1- or 3-days post IR and control mice (Ctrl).

Project description:Platelet homeostasis is essential for vascular integrity and immune defense. While the process of platelet formation by fragmenting megakaryocytes (thrombopoiesis) has been extensively studied, the cellular and molecular mechanisms required to constantly replenish the pool of megakaryocytes (MKs) by their progenitor cells (megakaryopoiesis) remains unclear. Here we use intravital imaging to track the cellular dynamics of megakaryopoiesis over days. We identify plasmacytoid dendritic cells (pDCs) as homeostatic sensors that monitor the bone marrow for apoptotic MKs and deliver IFN- to the MK niche triggering local on-demand proliferation and maturation of MK progenitors. This fine-tuned coordination between thrombopoiesis and megakaryopoiesis is crucial for MK and platelet homeostasis in steady state and stress. However, excessive activation of pDCs, such as by viral infections, can disturb this homeostatic circuit. Accordingly, we show that pDCs activated by SARS-CoV2 drive inappropriate megakaryopoiesis. Together, we uncover a hitherto unknown pDC-dependent homeostatic circuit that involves innate immune sensing and demand-adapted release of inflammatory mediators to maintain tissue homeostasis of the megakaryocytic lineage.

Project description:Immune thrombocytopenia (ITP) is a complicated bleeding disease characterized by sharp platelet reduction. As a dominating element involved in ITP, megakaryocytes (MKs) are responsible for thrombopoiesis. However, the mechanism behind the dysregulation of thrombopoiesis in ITP remains undetermined. In this study, we examined the role of YAP1, Yes-associated protein 1, in thrombopoiesis during ITP. We observed a reduced YAP1 expression with cytoskeletal actin misalignment in MKs of ITP patients. Using experimental ITP mice, we showed that YAP1 reduction induced aberrant MK distribution, reduced the percentage of late MKs in total MKs, and caused submaximal platelet recovery. Mechanistically, YAP1 upregulation by GATA1 binding to its promoter promoted MK maturation. Phosphorylated YAP1 facilitated cytoskeletal activation by binding of its WW2 domain to MYH9, facilitating thrombopoiesis. Targeting YAP1 by its activator XMU-MP-1 was sufficient to rescue cytoskeleton defects and thrombopoiesis in YAP1+/- ITP mice and ITP patients. Taken together, these results demonstrate a crucial role for YAP1 in thrombopoiesis, providing a potential for the development of diagnostic markers and therapeutic options for ITP.

Project description:Immune thrombocytopenia (ITP) is a complicated bleeding disease characterized by sharp platelet reduction. As a dominating element involved in ITP, megakaryocytes (MKs) are responsible for thrombopoiesis. However, the mechanism behind the dysregulation of thrombopoiesis in ITP remains undetermined. In this study, we examined the role of YAP1, Yes-associated protein 1, in thrombopoiesis during ITP. We observed a reduced YAP1 expression with cytoskeletal actin misalignment in MKs of ITP patients. Using experimental ITP mice, we showed that YAP1 reduction induced aberrant MK distribution, reduced the percentage of late MKs in total MKs, and caused submaximal platelet recovery. Mechanistically, YAP1 upregulation by GATA1 binding to its promoter promoted MK maturation. Phosphorylated YAP1 facilitated cytoskeletal activation by binding of its WW2 domain to MYH9, facilitating thrombopoiesis. Targeting YAP1 by its activator XMU-MP-1 was sufficient to rescue cytoskeleton defects and thrombopoiesis in YAP1+/- ITP mice and ITP patients. Taken together, these results demonstrate a crucial role for YAP1 in thrombopoiesis, providing a potential for the development of diagnostic markers and therapeutic options for ITP.

Project description:The hematopoietic system gives rise to a heterogeneous population of terminally differentiated cells that reside in the bone marrow (BM) to fulfill their roles in immunity, blood clotting and tissue oxygenation. Hematopoietic stem and progenitor cells are at the apex of a hierarchically organized maturation cascade constantly replenishing the pool of differentiated cells to maintain blood cell homeostasis. The bone marrow microenvironment is functionally compartmentalized by heterogeneous niche cells that provide physical and soluble signals to spatio-temporally organize hematopoiesis. Megakaryocytes (MKs) are niche cells of hematopoietic origin that support hematopoietic stem cell (HSCs) homeostasis and generate circulating platelets. Platelet production involves the release of MK fragments while their cell body is entirely consumed in a process termed thrombopoiesis. Consequently, replenishment of fragmented MKs from MK progenitors (termed megakaryopoiesis) is required to ensure sufficient platelet production, but also to maintain MK homeostasis within the HSC niche. Here, we used intravital imaging of the megakaryocytic lineage to identify the spatio-temporal patterns of megakaryopoiesis during steady state and thrombocytopenia. We show that MK consumption during thrombopoiesis is compensated by immediate and local proliferation of MK progenitors. MK homeostasis is controlled by plasmacytoid dendritic cells (pDCs) that scan the BM and secrete Interferon alpha (INFa) upon detection of exhausted megakaryocytes to trigger megakaryopoiesis. We identified local pDC-derived INFa release as a physiological inflammatory stimulus of the bone marrow niche that synchronizes megakaryopoiesis and thrombopoiesis to maintain homeostasis of MKs and platelets in steady state and under stress. Viral infection with SARS-CoV-2 can manipulate pDC-driven MK proliferation leading to inappropriate megakaryopoiesis, which has been associated with thrombotic complications during COVID-19.

Project description:d9 and d12 Mks were either cultured statically or subjected to shear flow for 30 min; at d9, half the Mks were placed back in culture for 30 min (60 min time point) Megakaryocytes (Mks) are exposed to shear flow as they migrate from the bone marrow hematopoietic compartment into circulation thus releasing platelets and pro/preplatelets directly into the blood stream. Shear forces have been now established as promoting Mk maturation and platelet biogenesis. In order to understand the underlying mechanisms that modulate the response of Mks to shear forces, we carried out transcriptional analysis on immature and mature stem cell-derived Mks that were exposed to physiologically-relevant shear (2.5 dyn/cm2). In immature (d9) Mks, shear exposure upregulated genes related to growth and Mk maturation, while in mature (d12) Mks, it upregulated genes involved in apoptosis and intracellular transport. Following shear-flow exposure, 6 AP-1 transcripts (ATF4, JUNB, JUN, FOSB, FOS, and JUND) were upregulated at d9 and two AP-1 proteins (JunD and c-Fos) were upregulated both at d9 and d12. Our data show that MAPK signaling is linked to both the shear-stress response and AP-1 upregulation. JNK phosphorylation increased significantly following shear stimulation, while JNK inhibition reduced shear-induced JunD protein expression. Although p38 phosphorylation did not increase following shear flow, its inhibition reduced shear-induced JunD and c-Fos protein expression. JNK inhibition reduced fibrinogen binding of d9 and d12 platelet-like particle s (PLPs) and P-selectin expression at d12 PLPs, while p38 inhibition reduced fibrinogen binding of d12 PLPs. Here we show that mechanotransduction of shear forces in Mks results in JNK activation, AP-1 upregulation, and downstream transcriptional changes that promote maturation of immature Mks and platelet biogenesis in mature Mks. Two- and Three-condition experiment (flow vs. static culture condition, d9 vs. d12, and 30 min vs. 60 min at d9); Biological replicates: 3; Technical replicates: 1 (dye-swap)

Project description:d9 and d12 Mks were either cultured statically or subjected to shear flow for 30 min; at d9, half the Mks were placed back in culture for 30 min (60 min time point) Megakaryocytes (Mks) are exposed to shear flow as they migrate from the bone marrow hematopoietic compartment into circulation thus releasing platelets and pro/preplatelets directly into the blood stream. Shear forces have been now established as promoting Mk maturation and platelet biogenesis. In order to understand the underlying mechanisms that modulate the response of Mks to shear forces, we carried out transcriptional analysis on immature and mature stem cell-derived Mks that were exposed to physiologically-relevant shear (2.5 dyn/cm2). In immature (d9) Mks, shear exposure upregulated genes related to growth and Mk maturation, while in mature (d12) Mks, it upregulated genes involved in apoptosis and intracellular transport. Following shear-flow exposure, 6 AP-1 transcripts (ATF4, JUNB, JUN, FOSB, FOS, and JUND) were upregulated at d9 and two AP-1 proteins (JunD and c-Fos) were upregulated both at d9 and d12. Our data show that MAPK signaling is linked to both the shear-stress response and AP-1 upregulation. JNK phosphorylation increased significantly following shear stimulation, while JNK inhibition reduced shear-induced JunD protein expression. Although p38 phosphorylation did not increase following shear flow, its inhibition reduced shear-induced JunD and c-Fos protein expression. JNK inhibition reduced fibrinogen binding of d9 and d12 platelet-like particle s (PLPs) and P-selectin expression at d12 PLPs, while p38 inhibition reduced fibrinogen binding of d12 PLPs. Here we show that mechanotransduction of shear forces in Mks results in JNK activation, AP-1 upregulation, and downstream transcriptional changes that promote maturation of immature Mks and platelet biogenesis in mature Mks.

Project description:Megakaryocytes (MKs) and platelets are recognized mediators of inflammation and altered immunity. While antiplatelet therapies are widely used to prevent cardiovascular events, their role in attenuating platelet-mediated inflammation is uncertain. This study was designed to investigate the transcriptomic effect of APT on MKs and its impact on proinflammatory pathways. We demonstrated a significant effect on the MK transcriptome following P2Y12 receptor inhibition. Specifically, we found a significant downregulation of IFN pathways with P2Y12 receptor inhibition. In conclusion, targeting the P2Y12 receptor modulates MK and platelet inflammatory signaling pathways. P2Y12-mediated suppression of MK IFNα signaling may benefit proinflammatory diseases