Bone marrow | EPFL Graph Search

Bone marrow is a semi-solid tissue found within the spongy (also known as cancellous) portions of bones. In birds and mammals, bone marrow is the primary site of new blood cell production (or haematopoiesis). It is composed of hematopoietic cells, marrow adipose tissue, and supportive stromal cells. In adult humans, bone marrow is primarily located in the ribs, vertebrae, sternum, and bones of the pelvis. Bone marrow comprises approximately 5% of total body mass in healthy adult humans, such that a man weighing 73 kg (161 lbs) will have around 3.7 kg (8 lbs) of bone marrow. Human marrow produces approximately 500 billion blood cells per day, which join the systemic circulation via permeable vasculature sinusoids within the medullary cavity. All types of hematopoietic cells, including both myeloid and lymphoid lineages, are created in bone marrow; however, lymphoid cells must migrate to other lymphoid organs (e.g. thymus) in order to complete maturation. Bone marro

Characterization of STAT1-/- mice & Investigation of IFN alpha/beta production in murine bone marrow in response to injury

Yulia Kirpicheva

The hematopoietic system is a regenerative tissue with high cell turnover. Normal homeostasis of the hematopoietic system is insured by hematopoietic stem cells (HSCs). The important features of HSCs are the capacity to self-renew and multipotency. Multipotent HSCs perpetuate through life and are able to form all differentiated cell lineages of the blood. Most HSCs with long-term self-renewal capacity are quiescent and divide infrequently. However quiescent HSCs can be activated in response to injury. The signals responsible for the activation of quiescent HSCs are poorly investigated. The Trumpp laboratory has recently identified a role for IFNα in activation of quiescent HSCs in vivo. Activation of HSCs by IFNα involves increased phosphorylation of STAT1. Therefore the role of STAT1 in the homeostasis of the hematopoietic system was investigated by characterization of the hematopoietic system in STAT1-/- mice. A 2-fold decrease in short-term HSC (ST-HSCs) and multipotent progenitors (MPPs) was observed in the bone marrow of STAT1-/- mice compared to C57Bl/6 (wild type) mice. Analysis of progenitors of HSCs also revealed a small increase in common myeloid progenitors (CMPs) and a small decrease in common lymphoid progenitors (CLPs) in the bone marrow of STAT1-/- mice. These results indicate that STAT1 play a role in the homeostasis of ST-HSCs and MPPs in bone marrow. Functional analysis of STAT1-/- LT-HSCs using in vivo long-term reconstitution assay suggests that STAT1-/- LT-HSCs can reconstitute lethally irradiated mice. Nevertheless further investigations are necessary to examine whether STAT1 plays a role in HSCs self-renewal. The unexpected role of IFNα in activation of quiescent HSCs leads to the hypothesis that endogenously produced IFNα might be important for activation of HSCs in response to injury. To address this we generated the mouse model MxCre;R26REYFP to monitor endogenous IFNα/β production in the bone marrow after injury. Our results suggest that IFNα/β is produced in response to 5-FU induced myeloid suppression and G-CSF treatment in vivo. The role of IFNα/β during the recovery phase after 5-FU induced myeloid suppression was investigated using IFNAR-/- mice. These results suggest that endogenous IFNα/β might be important for the mobilization of HSCs into the spleen induced in response to 5-FU

2008

The role of MYC in bone and in the hematopoietic stem cell niche

Maike Jaworski

The nuclear protein c-Myc is one of the most potent proto-oncogenes described. Its expression is found to be deregulated in more than 50 percent of human cancers, where it has been shown to control a number of biological processes including driving proliferation, cell growth and angiogenesis while inhibiting differentiation. The effects of c-Myc are highly cell type specific and include cell autonomous and non-cell autonomous processes. In order to examine the effect of excess amounts of c-Myc in bone, we have generated a mouse line expressing the tTA transactivator under the control of the mouse 2.3 kb col1a1 promoter (named Col1a1::tTA), which directs transgene expression to mature osteoblasts. By combining this transgene with the Tet-O-Myc allele, we generated a Col1a1::tTA; Tet-O-Myc double transgenic mouse model in which it is possible to inducibly express human c-MYC in osteoblasts during development and in the adult. We document that the used 'tet-off' system directs transgene expression to bones and that c-MYC can be completely repressed by treatment with doxycycline. Using this mouse model, we demonstrate that overexpression of c-MYC leads to remarkable changes in mutant bones, which depend greatly in their severity on the developmental time point of c-MYC induction. Unrestricted c-MYC expression, starting with the first emergence of mature osteoblasts in the fetal skeleton (∼E14.0), leads to lethality of the mutants at birth; their bones are shortened and thicker than in controls. Later induction of c-MYC allows survival, but leads to significant changes in bone morphology. Mutant bones develop a very irregular bone structure with signs of excessive bone formation. Surprisingly, this also correlates with definite signs of excessive osteoclast activity, which explains the formation of cavities seen in the bone matrix. Osteoblasts not only produce bone matrix, they are also very important niche cells for hematopoietic cells, especially for hematopoietic stem cells and B cells. We find that c-MYC overexpression severely impairs B lymphopoiesis and also observe signs of extramedullary hematopoiesis in the spleen, which is indicative of a compromised HSC environment in the bone marrow. Most strikingly, these animals develop frank osteosarcomas leading to a much reduced life span. Tumors arise in various bones, with the ribs and hips being the most prominent sites. These c-MYC driven tumors are very aggressive as is evident by their capacity to spontaneously metastasize to lung and liver, a rather rare phenomenon in mouse models, indicating that these tumors share important aspects of human osteosarcomas. Molecular analysis of c-MYC overexpressing osteoblasts has revealed a defect in their terminal differentiation program, rendering them incapable to progress from a relatively immature proliferative to a quiescent, calcified matrix producing state. To our knowledge this is the first report of experimental osteosarcoma formation, originating from a mature and lineage committed osteoblast population indicating that c-MYC may be able to de-differentiate more mature cells. In summary, our novel conditional mouse model showed that c-MYC expression in mature osteoblasts can lead to the formation of highly aggressive and metastatic osteosarcomas, a lethal disease in humans. This model will be the basis for further studies elucidating the molecular effects of c-MYC on de-differentiation and metastasis formation, processes, which remain poorly understood but are critical events in highly malignant cancers.

EPFL2009

Bioengineering human bone marrow models to elucidate the triggers of the stem cell niche

Queralt Vallmajó Martín

The bone marrow (BM) microenvironment, or niche, significantly affects behaviors of its resident stem cell populations. Disruptions in the BM niche contribute to a number of severe clinical pathologies. Discovery of novel therapeutic strategies for BM-related diseases necessitates development of superior preclinical models to study parameters affecting BM homeostasis. To address this, a poly(ethylene glycol) hydrogel featuring a particular crosslinking chemistry based on the enzyme transglutaminase factor XIII, dubbed TG-PEG, was utilized to engineer humanized bone marrow models. Its modular nature was exploited throughout this work to systematically evaluate contributions of biophysical, cellular, and biochemical BM niche components to stem cell biology. Stiffness of TG-PEG hydrogels was optimized for each cell type and individual application explored. For bone formation by bone marrow stromal cells (BMSCs), an intermediate stiffness was optimal and significantly improved total bone volume over softer TG-PEG gels or natural materials. Results indicated that stability of the scaffold was more important than their chemical and biological properties. Alternatively, for hematopoietic stem and progenitor cells (HSPCs), softer gels were optimal for preserving multipotency while promoting cell proliferation. A number of BM-specific stem and progenitor cell types with richly diverse functions were explored. Skeletal stem cells (SSCs) encapsulated in TG-PEG hydrogels demonstrated their ability to form de novo bone in healing critically sized calvaria defects in mice. Next, subcutaneous implantation of BMSC-laden gels revealed their significant contribution to formation of ossicles. For some BMSC donors, ossicles could be formed in absence of bone morphogenetic protein (BMP)-2 offering a novel tool to evaluate their intrinsic capacity. Later, titration of BMSC seeding densities and BMP-2 doses yielded optimal conditions for robust BM formation, regardless of donor, enabling reproducibility for follow-on studies involving BM models. In humanized mice, homing of HSPCs to BMSC-laden TG-PEG gels was observed. Finally, humanized xenograft models were employed to determine vulnerability of the BM niche to subversion by cancer cells simulating osteotropism for both leukemia and breast cancer metastasis. Molecular factors known to trigger particular cell reactions within the niche were also investigated. Including RGD cell-adhesion ligands, as well as matrix metalloproteinase (MMP)-susceptible crosslinks to render the gels degradable, were critical for facilitating migration of recruited BM cells from murine hosts in xenograft studies. Hyaluronic acid (HA), when added to the hydrogel backbone, conferred superior engraftment to transplanted BMSCs and afforded reduced immunogenicity. Incorporation of the Notch-signaling ligands Jagged1 or DLL-4 into soft TG-PEG gels during in vitro HSPC expansion substantially stimulated proliferation, but recovered cells could no longer ensure long-term reconstitution. Aging, trauma, or cancer can cause disruptions of the tightly controlled balance between cells and their microenvironment in the BM niche. This body of work presents a number of bioengineered tools optimized for studying how niche components are affected by or contribute to such pathologies. Further work with these or similar models will no doubt highlight key clinically relevant targets and inform novel therapeutic approaches.

EPFL2019