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:Asrij deletion in mice causes loss of HSC quiescence, myeloid skewing, reduced p53 and increased DNA damage, features attributed to aged hematopoietic stem cells (HSCs). To identify the pathways and processes driving the observed HSC aging-like phenotypes upon asrij depletion and to compare the asrij KO transcriptome with aged wild type HSCs, we performed RNA-seq gene expression profiling of Lin- Sca-1+ c-Kit+ CD150+ CD48- stem cells isolated from asrij KO or asrij floxed (control) mouse bone marrow. Our results identify Asrij as a potential driver of aging-like alterations in HSCs and the RNA-seq based transcriptome could help identify additional aging biomarkers and develop strategies to rejuvenate aged HSCs or prevent premature HSC aging.

Project description:Mature blood cells are maintained throughout life by hematopoietic stem cells (HSC). With aging, both HSC self-renewal as well as multi-lineage differentiation fidelity decline, a process determined by cell-intrinsic and –extrinsic factors. We here studied which aging-associated bone marrow (BM) alterations contribute to this process. Aged specific pathogen free (SPF) WT mice have increased systemic levels of microbial compounds compared to their young counterparts. This associates with increased steady-state IL-1a/b production by multiple BM cell populations. Aging-associated inflammatory transcriptional signatures and functional myeloid-differentiation bias in HSCs were mitigated in aged IL-1R1KO SPF and WT germ-free mice. Moreover, myeloid cells from aged mice produce more IL-1b and aged mice show higher and more durable IL-1a/b increase to lipopolysaccharide (LPS) challenges. Reducing inflammatory burden in aged mice by inhibiting IL-1 signaling or by antibiotic treatment rejuvenate HSCs functions. Collectively we define the microbiome-IL-1-IL1R1 axis as a key driver of HSC aging.

Project description:Hematopoietic aging is associated with decreased hematopoietic stem cell (HSC) self-renewal capacity and increased risk for myelodysplasia and leukemia. Deficient DNA repair contributes to the decline in HSC self-renewal capacity during aging and it remains unclear whether extrinsic signals can rejuvenate aged HSCs. Here, we demonstrate that augmentation of non-homologous end-joining (NHEJ) DNA repair in aged HSCs via treatment with epidermal growth factor (EGF) rejuvenates HSC function. Seven day culture of BM CD34-ckit+sca-1+lin- (34-KSL) HSCs from aged C57BL/6 mice with EGF suppressed myeloid skewing and increased production of multipotent CFU-granulocyte, erythroid, monocyte and megakaryocyte (CFU-GEMM) colonies. Aged, EGF-treated HSCs displayed increased donor multilineage engraftment in primary competitively transplanted mice and in secondary mice compared to mice transplanted with aged, control HSCs. Donor cell engraftment within the bone marrow (BM) KSL and SLAM+KSL HSC population was > 2-fold increased in mice transplanted with aged, EGF-treated HSCs. Systemic administration of EGF to aged mice for 6 weeks also increased long term – HSC self-renewal capacity as measured by increased donor bone marrow (BM) competitive repopulation in primary and secondary transplanted mice. Conversely, deletion of EGFR in Scl/Tal1+ hematopoietic cells was associated with increased myeloid skewing and depletion of LT-HSCs in middle aged mice. Mechanistically, EGF treatment decreased DNA damage in aged HSCs through activation of DNA PK-cs, Artemis and NHEJ repair. Inhibition of DNA PK-cs blocked EGF-mediated restoration of multipotent differentiation and suppression of myeloid skewing in aged HSCs, suggesting that the restoration of hematopoietic potential in aged HSCs is dependent on EGF-mediated activation of DNA PK-cs. EGF treatment also converted the transcriptome of aged HSCs from enrichment for genes involved in cell death and survival to genes involved in HSC generation and identity. These data suggest that extrinsic activation of EGFR signaling can restore key functional capacities in aged HSCs.

Project description:Hematopoietic stem cells (HSCs) exhibit considerable cell-intrinsic changes with age. Epigenetic alterations are one of the hallmarks of HSC aging, and profiling of DNA methylation and histone modifications has provided potential mechanisms that contribute to HSC aging. Chromatin accessibility reflects a comprehensive transcriptional network operating in cells; however, it has not yet been investigated in HSC aging. Here we performed an integrated analysis of aged HSCs on transcriptome, chromatin accessibilities, and histone modifications. Alterations in chromatin accessibility preferentially took place in HSCs with aging, the cells at the top of hematopoietic hierarchy, suggesting that the age-associated alterations in chromatin accessibility are memorized in HSCs and are inherited to downstream progenitor cells. However, most genes with differentially accessible regions (DARs) were not actively transcribed and kept poised for activation in aged HSCs. Motifs of ATF/CREB, STAT, and CNC family transcription factors were significantly enriched at DARs in aged HSCs. These transcription factors are activated in response to external stresses such as cytokine and inflammation signals and oxidative stresses, suggesting that the long-term exposure to such stress signals have changed chromatin accessibility in HSCs to augment responses by such trained HSCs to subsequent stimuli. In contrast, aged HSC-specific gene expression occurred mainly at gene loci with poised accessible regions but not DARs without accompanying drastic chromatin reorganization, suggesting that altered cell-extrinsic stimuli or signals from aged niche largely account for this process. Our findings provide key epigenetic molecular insights into HSC aging and serve as a reference for future analysis. 

Project description:Aged hematopoietic stem cells (HSCs) exhibit compromised reconstitution capacity and differentiation-bias towards myeloid lineage. However, the molecular mechanism behind it remains not fully understood. In this study, we evaluated the expression of 5 pseudouridine (Ψ) synthases between young and aged HSCs, and observed that three of them are increased during aging. Functional evaluation assay reveals that enforced PUS10 and PUS7 recapitulate the phenotype aged HSCs. The increase of PUS10 in aged HSCs is due to aging-declined CRL4DCAF1-mediated ubiquitination degradation signaling. Mechanistically, the destructive role of enforced PUS10 on HSCs is not achieved by its Ψ synthases activity, but through miR139, dysfunction of which impairs the reconstitution capacity of HSCs. Consistently, we observed no difference of tRNA pseudouridylation profile between young and aged HSPCs, while enforced PUS10 alters the microRNA profile in HSCs. Targeted dysfunction of Pus10 results in compromises the self-renewal capacity of HSC.

Project description:Aged hematopoietic stem cells (HSCs) exhibit compromised reconstitution capacity and differentiation-bias towards myeloid lineage. However, the molecular mechanism behind it remains not fully understood. In this study, we evaluated the expression of 5 pseudouridine (Ψ) synthases between young and aged HSCs, and observed that three of them are increased during aging. Functional evaluation assay reveals that enforced PUS10 and PUS7 recapitulate the phenotype aged HSCs. The increase of PUS10 in aged HSCs is due to aging-declined CRL4DCAF1-mediated ubiquitination degradation signaling. Mechanistically, the destructive role of enforced PUS10 on HSCs is not achieved by its Ψ synthases activity, but through miR139, dysfunction of which impairs the reconstitution capacity of HSCs. Consistently, we observed no difference of tRNA pseudouridylation profile between young and aged HSPCs, while enforced PUS10 alters the microRNA profile in HSCs. Targeted dysfunction of Pus10 results in compromises the self-renewal capacity of HSC.

Project description:Aged hematopoietic stem cells (HSCs) exhibit compromised reconstitution capacity and differentiation-bias towards myeloid lineage. However, the molecular mechanism behind it remains not fully understood. In this study, we evaluated the expression of 5 pseudouridine (Ψ) synthases between young and aged HSCs, and observed that three of them are increased during aging. Functional evaluation assay reveals that enforced PUS10 and PUS7 recapitulate the phenotype aged HSCs. The increase of PUS10 in aged HSCs is due to aging-declined CRL4DCAF1-mediated ubiquitination degradation signaling. Mechanistically, the destructive role of enforced PUS10 on HSCs is not achieved by its Ψ synthases activity, but through miR139, dysfunction of which impairs the reconstitution capacity of HSCs. Consistently, we observed no difference of tRNA pseudouridylation profile between young and aged HSPCs, while enforced PUS10 alters the microRNA profile in HSCs. Targeted dysfunction of Pus10 results in compromises the self-renewal capacity of HSC.

Project description:The bone marrow (BM) niche comprised of BM endothelial cells (BMECs) and LepR+ mesenchymal stromal cells (MSCs), plays a critical role in preserving the fitness of hematopoietic stem cells (HSCs). Aging is associated with defects in the BM niche that impair their ability to support HSC activity. However, mechanisms underlying age-related defects in the BM niche remain poorly understood. In this study, we identify BM niche derived Netrin-1 (NTN1) as a critical regulator of BM niche cell fitness during aging. Conditional deletion of NTN-1 specifically within BM MSCs or BMECs of young mice resulted in premature aging phenotypes within the BM niche including increased vascular leakiness, hypoxia, DNA damage and adiposity. On the other hand, supplementation of aged mice with NTN1 resulted in restoration of these hallmark niche defects and a rejuvenation of HSC activity. Mechanistically, we identify NTN1 as a critical regulator of DNA Damage Response (DDR) within BM niche cells and HSCs. In this experiment, RNA Seq analysis was performed on HSCs derived from young mice (3 month old), PBS treated aged mice (18 month old), and NTN1 treated aged mice (18 month old), to characterize transcriptional alterations within HSCs during aging, and following NTN1 treatment of aged mice.

Project description:Aging impacts negatively on hematopoiesis, with consequences for immunity and acquired blood cell disorders. While impairments in hematopoietic stem cell (HSC) function contribute to this, the in vivo dynamics of such changes remain obscure. Here, we integrate extensive longitudinal functional assessments of HSC-specific lineage tracing with single-cell transcriptome and epitope profiling. In contrast to recent suggestions from single-cell RNA sequencing alone, our data favor a defined structure of HSC/progenitor differentiation that deviates substantially from HSC-derived hematopoiesis following transplantation. Native age-dependent attrition in HSC differentiation manifests as a drastically reduced lymphoid output via an early lymphoid-primed progenitor (MPP Ly-I). While in vitro activation fails to rescue lymphoid differentiation from most aged HSCs, robust lymphopoiesis can be achieved by culturing elevated numbers of candidate HSCs. Therefore, our data position rare chronologically aged HSC clones, fully competent at producing lymphoid offspring, as prime target for approaches aimed to improve lymphopoiesis in the elderly.