Project description:Hematopoietic stem cell transplantation (HSCT) is successfully applied since the late 1950s, however, its efficacy still needs to be improved. A promising strategy is to transplant high numbers of pluripotent hematopoietic stem cells (HSCs). Therefore, an advanced ex vivo culture system is needed that supports the proliferation and maintains the pluripotency of HSC to override possible limitations in cell numbers gained from donors. To model the natural HSC niche in vitro and thus, to amplify high numbers of undifferentiated HSCs, we used an optimized HSC cell culture medium in combination with artificial 3D bone marrow-like scaffolds made of polydimethylsiloxane (PDMS). After 14 days in vitro (DIV) cell culture, we performed transcriptome and proteome analysis of the whole cell populations. Ingenuity pathway analysis (IPA) indicated that our 3D PDMS cell culture scaffolds activated interleukin, SREBP, mTOR and FOXO signaling pathways as well as the HSC metabolism, which we confirmed by ELISA, Western blot and metabolic flux analysis. These molecular signaling pathways and HSC metabolism are well known to promote the expansion HSCs and are involved in their pluripotency maintenance. After selection and enrichment of immature CD34-positive/CD38-negative HSCs using FACS sorting, we could confirm our findings by another proteome analysis followed by IPA. Thus, we could show that our 3D bone marrow-like PDMS scaffolds activate key molecular signaling pathways to amplify the numbers of undifferentiated HSC efficiently ex vivo.

Project description:Using RNA sequencing analysis on myeloid biased HSC, we compared gene expression profiles between WT and Igf2bp2 knock-out mice at young and old age. 1421 differentially expressed genes were identified in young myeloid biased HSC from Igf2bp2 knock-out mice compared to young WT; however, only 26 differentially expressed genes were identified in old myeloid biased HSC from Igf2bp2 knock-out mice compared to old WT. Compared to young WT myeloid biased HSC, myeloid biased HSC from young Igf2bp2 knock-out exhibits reduced expression of genes involved in metabolism and translation. In addition, single cell RNA sequencing analysis of myeloid biased HSC in young wildtype mice identified nine sub-clusters. HSCs from a sub-cluster with high expression of Igf2bp2 exhibit up-regulated IGF/PI3K/AKT signaling and increased expression of genes involved in HSC quiescence and maintenance. Altogether, the study provides a correlation and mechanism to understand the role of Igf2bp2 in HSC function and aging.

Project description:Aging of hematopoietic stem cells (HSCs) leads to several functional changes, including alterations affecting self-renewal and differentiation. While it is well established that many of the age-induced changes are intrinsic to HSCs, less is known about the stability of this state. Here, we entertained the hypothesis that HSC aging is driven by the acquisition of permanent genetic mutations. To examine this issue at a functional level in vivo, we applied induced pluripotent stem (iPS) cell reprogramming of aged hematopoietic progenitors and allowed the resulting aged-derived iPS cells to reform hematopoiesis via blastocyst complementation. Next, we functionally characterized iPS-derived HSCs in primary chimeras and following the transplantation of 're-differentiated' HSCs into new hosts; the gold standard to assess HSC function. Our data demonstrate remarkably similar functional properties of iPS-derived and endogenous blastocyst-derived HSCs, despite the extensive chronological and proliferative age of the former. Our results therefore favor a model in which an underlying, but reversible, epigenetic component is a hallmark of HSC aging rather than being driven by an increased DNA mutation burden. Hematopoietic stem cells (HSC) have been sorted out from young and aged steady-state mice, and from recipients transplanted with young and aged bone marrow. Generated iPS and commercially available ES cells were also sorted and analyzed.

Project description:Long-term hematopoietic stem cells (LT-HSCs) are responsible for lifelong maintenance and regeneration of the blood system. Loss of LT-HSC function is a major contributor to decline in hematopoietic function with aging, leading to increased rate of infection, poor vaccination response, and increased risk of hematologic malignancies. While cellular and molecular hallmarks of LT-HSC aging have been defined, a barrier to achieving the goal of extending healthy hematopoietic function into older age is the lack of understanding of the nature and timing of the initiating events that cause LT-HSC aging. Here we show that hallmarks of LT-HSC aging and decline in hematopoietic function accumulate by middle age in mice, and that the hematopoietic cell-extrinsic bone marrow (BM) microenvironment at middle age is necessary and sufficient to cause LT-HSC aging. Using unbiased transcriptome-based approaches, we identify decreased production of IGF1 by mesenchymal stromal cells (MSC) in the local middle-aged BM microenvironment as a factor causing LT-HSC aging and show that direct stimulation of middle-aged LT-HSCs with IGF1 rescues hallmarks of aging. Together, our study demonstrates that the initiating events causing LT-HSC and hematopoietic aging emerge by middle age and are caused by hematopoietic cell-extrinsic changes in the BM microenvironment. Declining IGF1 in the BM microenvironment at middle age represents a compelling target for intervention using prophylactic therapies to effectively extend healthspan and prevent decline in hematopoietic function during aging.

Project description:Long-term hematopoietic stem cells (LT-HSCs) are responsible for lifelong maintenance and regeneration of the blood system. Loss of LT-HSC function is a major contributor to decline in hematopoietic function with aging, leading to increased rate of infection, poor vaccination response, and increased risk of hematologic malignancies. While cellular and molecular hallmarks of LT-HSC aging have been defined1-3, a barrier to achieving the goal of extending healthy hematopoietic function into older age is the lack of understanding of the nature and timing of the initiating events that cause LT-HSC aging. Here we show that hallmarks of LT-HSC aging and decline in hematopoietic function accumulate by middle age in mice, and that the hematopoietic cell-extrinsic bone marrow (BM) microenvironment at middle age is necessary and sufficient to cause LT-HSC aging. Using unbiased transcriptome-based approaches, we identify decreased production of IGF1 by mesenchymal stromal cells (MSC) in the local middle-aged BM microenvironment as a factor causing LT-HSC aging and show that direct stimulation of middle-aged LT-HSCs with IGF1 rescues hallmarks of aging. Together, our study demonstrates that the initiating events causing LT-HSC and hematopoietic aging emerge by middle age and are caused by hematopoietic cell-extrinsic changes in the BM microenvironment. Declining IGF1 in the BM microenvironment at middle age represents a compelling target for intervention using prophylactic therapies to effectively extend healthspan and prevent decline in hematopoietic function during aging.

Project description:Long-term hematopoietic stem cells (LT-HSCs) are responsible for lifelong maintenance and regeneration of the blood system. Loss of LT-HSC function is a major contributor to decline in hematopoietic function with aging, leading to increased rate of infection, poor vaccination response, and increased risk of hematologic malignancies. While cellular and molecular hallmarks of LT-HSC aging have been defined1-3, a barrier to achieving the goal of extending healthy hematopoietic function into older age is the lack of understanding of the nature and timing of the initiating events that cause LT-HSC aging. Here we show that hallmarks of LT-HSC aging and decline in hematopoietic function accumulate by middle age in mice, and that the hematopoietic cell-extrinsic bone marrow (BM) microenvironment at middle age is necessary and sufficient to cause LT-HSC aging. Using unbiased transcriptome-based approaches, we identify decreased production of IGF1 by mesenchymal stromal cells (MSC) in the local middle-aged BM microenvironment as a factor causing LT-HSC aging and show that direct stimulation of middle-aged LT-HSCs with IGF1 rescues hallmarks of aging. Together, our study demonstrates that the initiating events causing LT-HSC and hematopoietic aging emerge by middle age and are caused by hematopoietic cell-extrinsic changes in the BM microenvironment. Declining IGF1 in the BM microenvironment at middle age represents a compelling target for intervention using prophylactic therapies to effectively extend healthspan and prevent decline in hematopoietic function during aging.

Project description:Long-term hematopoietic stem cells (LT-HSCs) are responsible for lifelong maintenance and regeneration of the blood system. Loss of LT-HSC function is a major contributor to decline in hematopoietic function with aging, leading to increased rate of infection, poor vaccination response, and increased risk of hematologic malignancies. While cellular and molecular hallmarks of LT-HSC aging have been defined1-3, a barrier to achieving the goal of extending healthy hematopoietic function into older age is the lack of understanding of the nature and timing of the initiating events that cause LT-HSC aging. Here we show that hallmarks of LT-HSC aging and decline in hematopoietic function accumulate by middle age in mice, and that the hematopoietic cell-extrinsic bone marrow (BM) microenvironment at middle age is necessary and sufficient to cause LT-HSC aging. Using unbiased transcriptome-based approaches, we identify decreased production of IGF1 by mesenchymal stromal cells (MSC) in the local middle-aged BM microenvironment as a factor causing LT-HSC aging and show that direct stimulation of middle-aged LT-HSCs with IGF1 rescues hallmarks of aging. Together, our study demonstrates that the initiating events causing LT-HSC and hematopoietic aging emerge by middle age and are caused by hematopoietic cell-extrinsic changes in the BM microenvironment. Declining IGF1 in the BM microenvironment at middle age represents a compelling target for intervention using prophylactic therapies to effectively extend healthspan and prevent decline in hematopoietic function during aging.

Project description:Hematopoietic stem cells (HSCs) balance self-renewal and differentiation to maintain hematopoietic fitness throughout life. In steady-state conditions, HSC exhaustion is prevented by the maintenance of most HSCs in a quiescent state, with cells entering the cell cycle only occasionally. HSC quiescence is regulated by retinoid and fatty-acid ligands of transcriptional factors of the nuclear retinoid X receptor (RXR) family. Here, we show that dual deficiency for hematopoietic RXRa and RXRb induces HSC exhaustion, myeloid cell/megakaryocyte differentiation, and myeloproliferative-like disease. RXRa and RXRb maintain HSC quiescence, survival, and chromatin compaction; moreover, transcriptome changes in RXRa;RXRb-deficient HSCs include premature acquisition of an aging-like HSC signature, MYC pathway upregulation, and RNA intron retention. Fitness loss and associated RNA transcriptome and splicing alterations in RXRa;RXRb-deficient HSCs are prevented by Myc haploinsufficiency. Our study reveals the critical importance of RXRs for the maintenance of HSC fitness and their protection from premature aging.

Project description:Hematopoietic stem cells (HSCs) balance self-renewal and differentiation to maintain hematopoietic fitness throughout life. In steady-state conditions, HSC exhaustion is prevented by the maintenance of most HSCs in a quiescent state, with cells entering the cell cycle only occasionally. HSC quiescence is regulated by retinoid and fatty-acid ligands of transcriptional factors of the nuclear retinoid X receptor (RXR) family. Here, we show that dual deficiency for hematopoietic RXRa and RXRb induces HSC exhaustion, myeloid cell/megakaryocyte differentiation, and myeloproliferative-like disease. RXRa and RXRb maintain HSC quiescence, survival, and chromatin compaction; moreover, transcriptome changes in RXRa;RXRb-deficient HSCs include premature acquisition of an aging-like HSC signature, MYC pathway upregulation, and RNA intron retention. Fitness loss and associated RNA transcriptome and splicing alterations in RXRa;RXRb-deficient HSCs are prevented by Myc haploinsufficiency. Our study reveals the critical importance of RXRs for the maintenance of HSC fitness and their protection from premature aging.

Project description:MTD project_description Inflammation and decreased stem cell function characterize organism aging, yet the relationship between these factors remains incompletely understood. This study shows that aged hematopoietic stem and progenitor cells exhibit increased ground-stage NF-κB activity, which enhances their responsiveness to undergo differentiation and loss of self-renewal in response to inflammation. The study identifies Rad21/cohesin as a critical mediator of NF-κB signals, by increasing chromatin accessibility of inter-/intra-genic and enhancer regions. Rad21/NF-κB are required for normal differentiation, but limit self-renewal of hematopoietic stem cells (HSCs) during aging and inflammation in an NF-κB dependent manner. HSCs from aged mice fail to downregulate Rad21/cohesin and inflammation/differentiation inducing signals in the resolution phase after acute inflammation. and The inhibition of cohesin/NF-κB is sufficient to revert the hypersensitivity of aged HSPCs to inflammation-induced differentiation. During aging, myeloid-biased HSCs with disrupted and naturally occurring reduced expression of Rad21/cohesin are increasingly selected over lymphoid-biased HSCs. Together, Rad21/cohesin mediated NF-κB signaling limits HSPC function during aging and selects for cohesin deficient HSCs with myeloid skewed differentiation.