Project description:Replication stress is a main driver of functional decline of hematopoietic stem cells (HSCs), which carry the highest burden of maintaining genomic integrity and functionality within the hematopoietic system. Here, we identify a novel signaling axis in which β-catenin and Hoxa9 function in a compensatory manner to preserve HSC functionality by protecting DNA replication dynamics and genomic integrity, in part via regulation of Prmt1 activity. Co-inactivation of β-catenin and Hoxa9 induces severe hematopoietic defects accompanied by accumulating replication stress and DNA damage resulting in functional HSC decline. Furthermore, we illustrate how β-catenin and Hoxa9 pathways converge on the pivotal downstream target, Prmt1, which functions to maintain an adequate supply of DNA replication and repair factors. Prmt1 aids in alleviating replication stress and DNA damage accumulation thereby preserving HSC integrity and functionality.

Project description:Replication stress is a main driver of functional decline of hematopoietic stem cells (HSCs), which carry the highest burden of maintaining genomic integrity and functionality within the hematopoietic system. Here, we identify a novel signaling axis in which β-catenin and Hoxa9 function in a compensatory manner to preserve HSC functionality by protecting DNA replication dynamics and genomic integrity, in part via regulation of Prmt1 activity. Co-inactivation of β-catenin and Hoxa9 induces severe hematopoietic defects accompanied by accumulating replication stress and DNA damage resulting in functional HSC decline. Furthermore, we illustrate how β-catenin and Hoxa9 pathways converge on the pivotal downstream target, Prmt1, which functions to maintain an adequate supply of DNA replication and repair factors. Prmt1 aids in alleviating replication stress and DNA damage accumulation thereby preserving HSC integrity and functionality.

Project description:Replication stress is a main driver of functional decline of hematopoietic stem cells (HSCs), which carry the highest burden of maintaining genomic integrity and functionality within the hematopoietic system. Here, we identify a novel signaling axis in which β-catenin and Hoxa9 function in a compensatory manner to preserve HSC functionality by protecting DNA replication dynamics and genomic integrity, in part via regulation of Prmt1 activity. Co-inactivation of β-catenin and Hoxa9 induces severe hematopoietic defects accompanied by accumulating replication stress and DNA damage resulting in functional HSC decline. Furthermore, we illustrate how β-catenin and Hoxa9 pathways converge on the pivotal downstream target, Prmt1, which functions to maintain an adequate supply of DNA replication and repair factors. Prmt1 aids in alleviating replication stress and DNA damage accumulation thereby preserving HSC integrity and functionality.

Project description:Beta-catenin signaling is required for establishment of leukemic stem cells (LSCs) in acute myeloid leukemia (AML), yet the upstream regulators that can augment this pathway are unknown. Through genome-wide gene expression analysis and functional studies, we identified an important role for GPR84 in MLL AML. Suppression of GPR84 significantly inhibited cell growth in pre-LSCs, reduced LSC frequency and impaired reconstitution of MLL AML. Furthermore, GPR84 conferred a growth advantage to Hoxa9/Meis1a transduced hematopoietic stem cells (HSCs). Our microarray analysis demonstrated that GPR84 overexpression significantly up-regulated a small set of MLL-fusion targets and beta-catenin co-effectors, and down-regulated a hematopoietic cell cycle inhibitor. These data thus reveal a previously unrecognized role of GPR84 in the maintenance of fully developed AML by sustaining aberrant beta-catenin signaling in LSCs. HSC-derived Hoxa9/Meis1a pre-LSCs were transduced with GPR84 cDNA or empty vector, and replated in methylcellulose supplemented with cytokines. Each group contains triplicate samples.

Project description:From mice, strand-specific RNA-Seq of granulocyte-myeloid progenitors (GMP) and hematopoietic stem cells (HSC). Cancer stem cells (CSC) were created with MLL-ENL transfections using puromycin for both GMP and HSCs. Further knock-outs were created of -catenin (Ctnnb1) and Hoxa9.

Project description:Activation of mostly quiescent hematopoietic stem cells (HSC) is a prerequisite for life-long blood production1, 2. This process requires major molecular adaptations to meet the regulatory and metabolic requirements for cell division3-8. The mechanisms governing cellular reprograming upon stem cell activation and their subsequent return to quiescence are still not fully characterized. Here, we describe a role for chaperone-mediated autophagy (CMA)9, a selective form of lysosomal protein degradation, in sustaining adult HSC function. CMA is required for stem cell protein quality control and upregulation of fatty acid metabolism upon HSC activation. We identify that CMA activity decreases with age in HSC and show that genetic or pharmacological activation of CMA can restore functionality of old HSC. Together, our findings provide mechanistic insights into a new role for CMA in sustaining quality control, appropriate energetics and overall long-term hematopoietic stem cell function. Our work supports that CMA may be a promising therapeutic target to enhance hematopoietic stem cell function in conditions such as aging or stem cell transplantation.

Project description:During embryogenesis, development of hematopoietic stem cells (HSC) occurs in the fetal liver and involves coordinate programs of transcription. Taspase1, a highly conserved threonine protease, directly cleaves and regulates the TFIIA families of transcription factors. We discovered that loss of Taspase1 (Tasp1-/-) or non-cleavage of TFIIAα−β (TFIIAα-βnc/nc) leads to a severe fetal liver developmental retardation that is associated with impaired HSC self-renewal and loss of HSC quiescence. We used microarray to elucidate the mechanism(s) by which TFIIA regulates fetal liver hematopoiesis, and expression of targets of HoxA9 was found to be altered by gene set enrichment analyses.

Project description:The zinc finger protein and SNAG domain transcription factor Gfi1b is highly expressed in hematopoietic stem cells (HSC) and in megakaryocytes (MKs). Deletion of Gfi1b in mice leads to a drastic expansion of both cell types, suggesting that Gfi1b controls their proliferation. Here we present evidence that Gfi1b exerts this control by modulating the Wnt/beta-catenin signaling pathway. We can show that Gfi1b binds to beta-catenin and is part of a larger complex that contains β-catenin co-factors. Gfi1b activates beta-catenin/TCF mediated transcription and is required for the activity of beta-catenin target gene promoter driven reporter genes in vivo. This is dependent of the ability of Gfi1b to recruit the histone modifying enzyme lysine demethylase 1 (LSD1) to β-catenin containing complexes. Moreover, LSD1 enhances the Gfi1b-mediated activation of beta-catenin/TCF dependent transcription. Both Gfi1b deficient HSCs and MKs show de-regulation of expression of many sets on Wnt/β-catenin target genes and Gfi1b and β-catenin co-occupy the promoters of many common target genes. Finally, activating the Wnt/β-catenin signaling pathway in Gfi1b deficient HSCs and MKs significantly reduces their expansion, which confirms that Gfi1b is a critical factor controlling the cellularity of HSCs and MKs and exerts this function by regulating the Wnt/β-catenin pathway in these cells.

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.