Project description:Demonstration of hematopoietic stem cells (HSCs) was first shown in the mouse and was dependent on recipient bone marrow (BM) to support in vivo multilineage hematopoietic reconstitution, thereby illustrating non-cell-autonomous requirements for HSC functions. Murine studies have defined microanatomic compartments in the BM comprised of osteoblasts, mesenchymal cells, subsets of vasculature, and innervating neural cells functioning as an HSC-supportive niche. Despite the potential clinical applications, analyses of putative HSCs in the BM of humans has not been examined. Here, using human bone biopsies, we provide evidence of HSC propensity to endosteal regions of Trabecular Bone Area (TBA). Independent of phenotypic definitions based on prospective isolation, functional studies indicate that human HSCs residing in the TBA of human and transplanted recipients had superior regenerative and self-renewal capacity and are molecularly distinct to those repopulating the Long Bone Area (LBA). Consistent with the non-cell-autonomous nature of HSC function, osteoblasts in the TBA possess unique characteristics and expressed a key network of factors including those involving Notch activity which could regulate TBA vs. LBA location of human HSCs in vivo. Our study illustrates that human-mouse xenografts provide a surrogate to indigenous human HSC in the BM, and demonstrates that BM architecture plays a critical role in defining functional properties of human HSCs.

Project description:Demonstration of hematopoietic stem cells (HSCs) was first shown in the mouse and was dependent on recipient bone marrow (BM) to support in vivo multilineage hematopoietic reconstitution, thereby illustrating non-cell-autonomous requirements for HSC functions. Murine studies have defined microanatomic compartments in the BM comprised of osteoblasts, mesenchymal cells, subsets of vasculature, and innervating neural cells functioning as an HSC-supportive niche. Despite the potential clinical applications, analyses of putative HSCs in the BM of humans has not been examined. Here, using human bone biopsies, we provide evidence of HSC propensity to endosteal regions of Trabecular Bone Area (TBA). Independent of phenotypic definitions based on prospective isolation, functional studies indicate that human HSCs residing in the TBA of human and transplanted recipients had superior regenerative and self-renewal capacity and are molecularly distinct to those repopulating the Long Bone Area (LBA). Consistent with the non-cell-autonomous nature of HSC function, osteoblasts in the TBA possess unique characteristics and expressed a key network of factors including those involving Notch activity which could regulate TBA vs. LBA location of human HSCs in vivo. Our study illustrates that human-mouse xenografts provide a surrogate to indigenous human HSC in the BM, and demonstrates that BM architecture plays a critical role in defining functional properties of human HSCs.

Project description:Demonstration of hematopoietic stem cells (HSCs) was first shown in the mouse and was dependent on recipient bone marrow (BM) to support in vivo multilineage hematopoietic reconstitution, thereby illustrating non-cell-autonomous requirements for HSC functions. Murine studies have defined microanatomic compartments in the BM comprised of osteoblasts, mesenchymal cells, subsets of vasculature, and innervating neural cells functioning as an HSC-supportive niche. Despite the potential clinical applications, analyses of putative HSCs in the BM of humans has not been examined. Here, using human bone biopsies, we provide evidence of HSC propensity to endosteal regions of Trabecular Bone Area (TBA). Independent of phenotypic definitions based on prospective isolation, functional studies indicate that human HSCs residing in the TBA of human and transplanted recipients had superior regenerative and self-renewal capacity and are molecularly distinct to those repopulating the Long Bone Area (LBA). Consistent with the non-cell-autonomous nature of HSC function, osteoblasts in the TBA possess unique characteristics and expressed a key network of factors including those involving Notch activity which could regulate TBA vs. LBA location of human HSCs in vivo. Our study illustrates that human-mouse xenografts provide a surrogate to indigenous human HSC in the BM, and demonstrates that BM architecture plays a critical role in defining functional properties of human HSCs. Lin- MNCs from human Umbilical Cord blood (CB) were injected via tail vein into sublethally irradiated NOD/SCID adult mice. After 10 weeks post-transplantation, engrafted-CB cells were sorted based on the co-expression of CD45 and CD34, and absence or presence of CD38 using a FACSAria II (BD). Total RNA from purified populations was extracted and amplified as described previously (Shojaei et al., 2005). Amplified-labeled RNA was hybridized to HG-U133Plus v2.0 chip.

Project description:Under stress hematopoiesis, previous studies have suggested the migration of hematopoietic stem cells (HSCs) from bone marrow (BM) to extramedullary sites such as spleen. However, there is little direct evidence of HSC migration from BM to spleen. Here, we induced myeloablation via 5-fluorouracil (5-FU) and showed the direct evidence of HSC migration from BM to spleen during hematopoietic regeneration via a photoconvertible fluorophore. We found that during hematopoietic regeneration, there were mechanistic differences for HSC migration during early (day 3 to 8) and late phase (day 11 to 14). During steady-state, HSCs preferentially migrated to BM rather than spleen, but during the early phase HSC migration to spleen predominated. Indeed, in the early phase, HSC mobilization from BM was induced in G-CSF-dependent manners, while HSCs in the late phase gained significantly enhanced cell-autonomous motility, which was independent of chemotaxis. Collectively, HSC migration was dynamically changed during hematopoietic regeneration.

Project description:Recent advances have taken advantage of various animal models in HSC aging research, including certain gene mutations, chemicals, and ionizing radiation (IR). To identify the underlying mechanisms and phenotype switching in HSC aging, we employed IR-induced premature HSC aging model and performed RNA-seq of HSCs from the bone marrow (BM) of mice at three months post IR and their age-matched control mice (Ctrl).

Project description:Regulation of hematopoietic stem cells (HSCs) by bone marrow (BM) niches has been extensively studied; however, whether and how HSC subpopulations are distinctively regulated by BM niches remain unclear. Here, we functionally distinguished reserve HSCs (rHSCs) from primed HSCs (pHSCs) based on their response to chemotherapy and examined how they are dichotomously regulated by BM niches. Both pHSCs and rHSCs supported long-term hematopoiesis in homeostasis; however, pHSCs were sensitive but rHSCs were resistant to chemotherapy. Surviving rHSCs restored the HSC pool and supported hematopoietic regeneration after chemotherapy. The rHSCs were preferentially maintained in the endosteal region that enriches N-cadherin+ (Ncad+) bone-lining cells in homeostasis and post-chemotherapy. N-cad+ cells were functional bone and marrow stromal progenitor cells (BMSPCs), giving rise to osteoblasts, adipocytes, and chondrocytes in vitro and in vivo. Finally, ablation of Ncad+ niche cells or deletion of SCF from N-cad+ niche cells impaired rHSC maintenance during homeostasis and regeneration.

Project description:To investigate how HSCs functionally compensate for the B cell deficiencies of other HSCs within an organism, we co-transplanted wildtype (WT) HSCs and lineage-deficient HSCs into lethally irradiated WT recipient mice. WT HSCs were then purified from the bone marrow of recipient mice for RNA isolation and sequencing. The purpose is to determine whether there are common genes shared between compensating WT HSCs in the WT co-transplanted with uMT-/- (B6.129S2(B6)-Ighmtm1Cgn/J) and WT co-transplanted with NSG (NOD-scid IL2Rgamma null).

Project description:Severe infections are a major stress on haematopoiesis, where the consequences for haematopoietic stem cells (HSCs) have only recently started to emerge. HSC function critically depends on the integrity of complex bone marrow (BM) niches, however whether the BM microenvironment plays a role in mediating the effects of infection on HSCs remains an open question. Here, using a murine model of malaria and combining single cell RNA sequencing, mathematical modelling, transplantation assays and intravital microscopy, we show that haematopoiesis is reprogrammed upon infection, whereby the HSC compartment turns over significantly faster than in steady-state and HSC function is drastically affected as a result. Interferon is found to affect both haematopoietic and mesenchymal BM cells and we specifically identify a dramatic loss of osteoblasts and alterations in endothelial cell function. Osteo-active parathyroid hormone treatment abolishes infection-triggered HSC proliferation and, coupled with Reactive Oxygen Species quenching, enables partial rescuing of HSC function.

Project description:Gene expression of HSC (Lin-Sca-Kit+Flt3-) hematopoietic stem cells from Dicer D/+ mice was compared with LT-HSC from DicerD/D mice. BM cells were noncompetitively transplanted into irradiant recipients, and deletion induced by poly(IC) injection. Donor-derived HSCs were isolated by FACS sorting of recipient bone marrow. Biological replicates of each (2 per genotype) were generated and expression profiles were determined by hybridization to Affymetrix Moe430_2 arrays.

Project description:Gene expression analysis on purified murine hematopoietic stem cells (HSCs) deficient for Special AT-rich sequence-binding protein 1 (Satb1) compared to wild-type HSCs. Analysis of gene expression of bone marrow-derived CD45.2+ CD150+cKit+Sca-1+CD4-CD8a-CD19-B220-Gr-1- HSCs from congenic recipient animals transplanted >20 weeks with either wild-type or Satb1-deficient hematopoeitic cells.