Project description:The aging of hematopoietic stem cells (HSCs) significantly alters their characteristics. Mitochondria, essential for cellular metabolism, play a crucial role, and their dysfunction is a hallmark of aging-induced changes. The impact of mitochondrial mass on aged HSCs remains incompletely understood. Here, we demonstrate that HSCs with high mitochondrial mass during aging are not merely cells that have accumulated damaged mitochondria and become exhausted. Instead, these HSCs retain a high regenerative capacity and remain in the aging bone marrow. Furthermore, we identified GPR183 as a novel marker characterizing aged HSCs through single-cell analysis. HSCs marked by GPR183 were also enriched in aged HSCs with high mitochondrial mass, possessing a high capacity of self-renewal. These insights deepen our understanding of HSC aging and provide new perspectives on the assessment of aged HSCs, underscoring the importance of mitochondrial dynamics in the aging.

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:Aged hematopoietic stem cells (HSCs) display myeloid-biased differentiation and reduced regenerative potential. In this study, we uncover that P-selectin (Selp) marks a subset of aged HSCs with reduced repopulation capacity. This population of HSCs expresses a prominent aging transcriptome. Overexpression of Selp in young HSCs impaired long-term reconstitution potential and repressed erythropoiesis. We show that IL-1β is elevated in aged bone marrow and administration of IL-1β induces expression of Selp and other aging-associated genes in HSCs. Finally, we demonstrate that transplantation of aged HSCs into young recipients restores a young-like transcriptome, specifically by repressing pro-inflammatory pathways, highlighting the important role of the bone marrow microenvironment in HSC aging.

Project description:Aging leads to a decline in function of hematopoietic stem cells (HSCs) and increases susceptibility to hematological disease. We found CD61 to be highly expressed in aged HSCs. Here we investigate the role of CD61 in identifying distinct subpopulations of aged HSCs and assess how expression of CD61 affects stem cell function. We show that HSCs with high expression of CD61 are functionality superior and retain self-renewal capacity in serial transplantations. A population of aged HSCs with highest CD61 expression is functionally comparable to young HSCs. These CD61High HSCs display a notably higher quiescence compared to their CD61Low counterparts. We also show that CD61High and CD61Low HSCs are transcriptomically distinct populations within aged HSCs. Collectively, our research identifies CD61 as a key player in maintaining stem cell quiescence during aging, ensuring the preservation of their functional integrity and potential. Moreover, CD61 emerges as a marker to prospectively isolate a superior, highly dormant population of young and aged HSCs, making it a valuable tool both in fundamental and clinical research.

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 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:Aging is a process accompanied by functional decline in tissues and organs with great social and medical consequences. Previous studies have demonstrated that aged hematopoietic stem cells (HSCs) are functionally compromised, which at least partly contributes to aging-related decline of the body health. However, the underlying mechanism is largely unknown. Here we reveal a clear heterogeneity of old HSCs, which can be marked by the CD150 levels. Comparative molecular and functional analyses revealed that CD150low HSCs from old mice have a younger aging clock, transcriptome, and better repopulation capacity compared to that of the CD150high HSCs. Mechanistically, CD150high HSCs from old mice have greatly compromised differentiation capacity compared to that of the CD150low HSCs. Importantly, decreasing the CD150high HSC ratio in old mice can alleviate aging-related functional decline. Thus, our study not only reveals how HSC heterogeneity contributes to aging, but also points to a potential way for rejuvenation.

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.