Wnt3a is involved in the early stage of miPSC and mESC haemopoietic differentiation

The Wnt/β-catenin signalling pathway is important in regulating not only self-renewal of haemopoietic progenitors and stem cells but also haemopoietic differentiation of ESCs (embryonic stem cells). However, it is still not clear how it affects haemopoietic differentiation. We have used a co-culture system for haemopoietic differentiation of mouse ESCs and iPSCs (induced pluripotent stem cells) in which the Wnt3a gene-modified OP9 cell line is used as stromal cells. The number of both Flk1+ and CD41+ cells generated from both co-cultured mouse ESCs and mouse iPSCs increased significantly, which suggest that Wnt3a is involved in the early stages of haemopoietic differentiation of mouse ESCs and mouse iPSCs in vitro.     

Stem cell maintenance and commitment to differentiation in long-term cultures of murine marrow obtained from different spatial locations in the femur

Abstract. Murine bone marrow was separated into axial and marginal fractions in order to investigate the ability of cells from different spatial locations in the marrow to establish long-term cultures. The maintenance of haemopoiesis was significantly poor in long-term cultures of marginal marrow compared with axial or control (unfractionated marrow) cultures. Using techniques to further fractionate the axial or marginal marrow by depleting either stromal or haemopoietic cells, it was possible to investigate the relative importance of stromal and haemopoietic cell components. In the combinations studied, the more important determinant of effective in vitro haemopoiesis was the source of the haemopoietic cells rather than the stroma. The most effective stem cell maintenance and commitment to differentiation was observed when the source of the haemopoietic population was axial marrow. The data are consistent with axial marrow being a source of 'high quality' stem cells and this quality being an intrinsic property of the cells rather than one imposed by the stromal environment.     

Stem cell maintenance and commitment to differentiation in long-term cultures of murine marrow obtained from different spatial locations in the femur

Murine bone marrow was separated into axial and marginal fractions in order to investigate the ability of cells from different spatial locations in the marrow to establish long-term cultures. The maintenance of haemopoiesis was significantly poor in long-term cultures of marginal marrow compared with axial or control (unfractionated marrow) cultures. Using techniques to further fractionate the axial or marginal marrow by depleting either stromal or haemopoietic cells, it was possible to investigate the relative importance of stromal and haemopoietic cell components. In the combinations studied, the more important determinant of effective in vitro haemopoiesis was the source of the haemopoietic cells rather than the stroma. The most effective stem cell maintenance and commitment to differentiation was observed when the source of the haemopoietic population was axial marrow. The data are consistent with axial marrow being a source of 'high quality' stem cells and this quality being an intrinsic property of the cells rather than one imposed by the stromal environment.     

The role of growth factors in self-renewal and differentiation of haemopoietic stem cells

Haemopoietic stem cells in vivo proliferate and develop in association with stromal cells of the bone marrow. Proliferation and differentiation of haemopoietic stem cells also occurs in vitro, either in association with stromal cells or in response to soluble growth factors. Many of the growth factors that promote growth and development of haemopoietic cells in vitro have now been molecularly cloned and purified to homogeneity and various techniques have been described that allow enrichment (to near homogeneity) of multipotential stem cells. This in turn, has facilitated studies at the mechanistic level regarding the role of such growth factors in self-renewal and differentiation of stem cells and their relevance in stromal-cell mediated haemopoiesis. Our studies have shown that at least some multipotential cells express receptors for most, if not all, of the haemopoietic cell growth factors already characterized and that to elicit a response, several growth factors often need to be present at the same time. Furthermore, lineage development reflects the stimuli to which the cells are exposed, that is, some stimuli promote differentiation and development of multipotential cells into multiple cell lineages, whereas others promote development of multipotential cell into only one cell lineage. We suggest that, in the bone marrow environment, the stromal cells produce or sequester different types of growth factors, leading to the formation of microenvironments that direct cells along certain lineages. Furthermore, a model system has been used to show the possibility that the self-renewal probability of multipotential cells can also be modulated by the range and concentrations of growth factors present in the environment. This suggests that discrete microenvironments, preferentially promoting self-renewal rather than differentiation of multipotential cells, may also be provided by marrow stromal cells and sequestered growth factors.     

Cellular interactions between 3T3 cells and interleukin-3-dependent multipotent haemopoietic cells: a model system for stromal-cell-mediated haemopoiesis

With the aid of a multipotent stem cell line (FDCP-mix cells) co-cultured with either normal or irradiated Swiss 3T3, cellular interactions between stromal cells and haemopoietic stem cells were studied by electron microscopy and time-lapse video microscopy. When cultured in the presence of interleukin 3 (IL-3) but in the absence of stromal cells, the FDCP-mix cells have a characteristic blast morphology. In the absence of IL-3, the cells die unless they are co-cultured with marrow stromal cells or 3T3 cells. In the latter case, they attach, proliferate, and differentiate on both normal and irradiated Swiss 3T3 cell layers without the addition of extrinsic growth factor (IL-3). At the initial attachment sites of these two cell lines, cellular recognition seemed to be mediated by the formation of microvillus cytoplasmic projections and extracellular matrix. These areas may well be the sites of plasma-membrane-bound signalling/adhesional molecules between the interacting cells.     

Direct cell-cell communication in the blood-forming system

In mammals, bone marrow is the principal tissue where blood is formed during adult life. Paracrine factors are generally considered to control this process but there is considerable evidence that gap junctions are present in haemopoietic tissues. Gap junctions have been implicated in developmental and patterning roles, and we set out to characterize the cells which are coupled, and to provide evidence for their role(s) in blood cell formation. Direct cell-cell communication, shown by dye-transfer, occurs between haemopoietic cells and certain stromal cells. In culture these stromal cells form a mat in which they retain their dye-coupling properties. Freeze-fracture electron microscopy confirms that this coupling is via gap junctions. When haemopoietic cells are cultured on top of these mats dye spreads upwards from the stromal cells into the haemopoietic cells above. Experiments in which haemopoietic cells were cultured alone, with stromal cell conditioned medium, or in direct contact with stromal cell underlays, were therefore carried out. The results of these experiments provide evidence that gap junctional communication may be playing a vital role in maintaining populations of precursor cells which would otherwise differentiate into end cells, leading to the ultimate demise of the system.     

The development of radiation late effects to the bone marrow after single and chronic exposure

The marrow is a tissue distributed in numerous skeletal parts and works as an organ which is composed of a haemopoietic cell parenchyma and a supporting stroma. The pathophysiological mechanisms involved in the radiation-induced late effects depend mainly on the damage produced to each of these elements. Parenchymal cell damage ends with a failure of the stem cell pool to supply an adequate number of highly differentiated functional blood cells and is clinically manifested as aplastic anaemia or leukaemia. The effects of radiation on the haemopoietic stem cell can be measured by means of spleen colony forming units (CFU-S) in rodents. The self-maintaining capacity of the CFU-S was found to be lower than normal 16 weeks after a dose of 0.64 Gy. In larger animals it is only possible to measure the activity of some of the progenitor cells, estimating the number of granulocyte-macrophage colonies in culture (CFU-GM) as an indicator of stem cell changes. Their number in the blood is about 50 per cent of normal even 160 days after about 0.78 Gy. The stromal cells are also radiosensitive if measured with respect to their capacity to support long-term cell replication in vitro. Marrow fibrosis develops after single, repeated and chronic radiation exposure, and a dose of 40 Gy impairs the capacity of the marrow to support haemopoiesis.     

Transduction of a marker gene (Neor) into precursor cells of the hematopoietic microenvironment]

The attempt of retroviral transfer of the bacterial Neor gene into stromal precursor cells able to transfer haemopoietic microenvironment and to long-term support of haemopoiesis in vitro and in vivo was made. The existence of marker gene in stromal cells was established by the method of polymerase chain reaction. The transduced stromal precursor cells create normal haemopoietic microenvironment. The data obtained would be important for the further investigation of proliferation and differentiation of stromal precursor cells.     

Induction of stem cell cycling in mice increases their sensitivity to a chemical leukaemogen: implications for inherited genomic instability and the bystander effect

Preconception paternal irradiation (PPI) modifies haemopoietic and stromal tissues of offspring and increases risk of generating lympho-haemopopietic malignancy if those offspring are then exposed to a leukaemogen. We hypothesised that this increased risk was related to inherited damage which had caused increased stem cell proliferation rates. To test for this link, in vivo, rapid stem cell proliferation was established by giving sub-lethal irradiation (3Gy gamma-rays) and allowing 3 days recovery. At this stage, 60% of haemopoietic spleen colony-forming units (CFU-S) were in DNA-synthesis, compared to <10% in unirradiated controls. Two groups of mice, unirradiated controls and irradiated animals, were then injected with 50mg/kg methyl nitrosourea (MNU) and observed daily for onset of lympho-haemopoietic malignancy. In a further control group of 60 mice, irradiated but not injected with MNU, only one leukaemia developed. In unirradiated controls, 20% of the mice developed malignancies between 3 and 8 months later: in the irradiated, MNU-treated groups, 95% developed malignancies between 2 and 7 months later. Thus, at least one powerful potentiating mechanism for induction of lympho-haemopoietc malignancy following inherited damage can be related to haemopoietic stem cell proliferation. Genomic instability is exposed by cell proliferation and has been implicated in this type of damage. However, a regulatory stromal microenvironment plays a part in inducing that proliferation. Thus, the microenvironment is the effective "bystander" which is thought to promote and amplify genomic instability, and thereby influence the induction of malignancy both in PPI offspring and in mice with induced stem cell proliferation.     

Haemopoietic long-term bone marrow cultures from adult mice show osteogenic capacity in vitro on 3–dimensional collagen sponges

Abstract. Adult murine bone marrow cells, cultured under conditions for long-term haemopoietic marrow cultures, produce bone matrix proteins and mineralized tissue in vitro , but only after the adherent stromal cells were loaded on a 3-dimensional collagen sponge. Provided more than 8 × 10⁶ cells are loaded, mineralization as measured by ⁸⁵Sr uptake from the culture medium, occurred in this 3-dimensional configuration (3-D) within 6 days. In contrast if undisrupted marrow fragments (containing more than 10⁷ cells) are placed directly on a collagen sponge, then it requires more than 10 days before significant mineralization can similarly be detected. The 2-dimensional (2-D) long-term marrow culture system allows prior expansion of the stromal cells and some differentiation in an osteogenic direction within the adherent stromal layer. This is suggested by the presence of type I collagen and alkaline phos-phatase positive cells. However, synthesis of osteonectin and a bone specific protein, osteocalcin, as well as calcification are only observed in 3-D cultures. Electron microscopy demonstrated hydroxyapatite mineral on collagen fibres, osteoblast-like cells, fibroblasts, cells which accumulated lipids, and macrophages which were retained on the collagen matrices. Irradiation of confluent long-term bone marrow cultures, prior to their loading on the collagen sponge showed that haemopoietic stem cells are not necessary for the mineralization.     

Metabolically inactive 3T3 cells can substitute for marrow stromal cells to promote the proliferation and development of multipotent haemopoietic stem cells

When highly enriched multipotential spleen colony forming cells (CFU-S) obtained following fluorescence activated cell sorting (FACS-CFU-S) are cultured on marrow stromal cells, they undergo proliferation and development to produce mature haemopoietic cells (Spooncer et al., Nature, 316:62-64, 1985). We now show that FACS-CFU-S behave in a similar way when cultured on monolayers of 3T3 cells, indicating that the 3T3 cells can supply at least part of the environment which is representative of marrow stromal cells and provide, therefore, a system for studying stromal cell: haemopoietic cell interactions. We also demonstrate that IL-3-dependent multipotential stem cell lines (FDCP-Mix), but not a variety of other "committed" IL-3-dependent cell lines, resemble FACS-CFU-S in terms of their ability to proliferate and differentiate when cultured on 3T3 cells in the absence of IL-3. In this system, attachment of the FDCP-Mix to the 3T3 cells is critical for the subsequent maintenance of viability and stimulation of development of the cells. When the FDCP-Mix cells are physically separated from the 3T3 cells, they die and their death cannot be prevented by using 3T3-cell-conditioned medium. The extracellular matrix generated by 3T3 cells is not sufficient for promoting attachment or viability of the FDCP-Mix cells, indicating the importance of integral membrane components. However, attachment and development of FDCP-Mix cells occurs on 3T3 cells that have been lightly fixed with glutaraldehyde indicating that active metabolism is not essential for the effects promoted by the 3T3 cells. We suggest that the ability of FACS-CFU-S and FDCP-Mix cells to respond to 3T3 cells involves specific ligand/receptor interactions.     

The structural-functional organization of the bone marrow after lethal irradiation and the transplantation of syngeneic hematopoietic cells]

A study was made of the content and morphology of haemopoietic islands in the bone marrow of lethally irradiated CBA mice, and their change after transplantation of syngeneic haemopoietic cells. The data obtained show that the haemopoietic islands are reconstructed in the injured haemopoietic tissue due to the donor's bone-marrow nuclears. A new type of structural and functional associations, namely, stromal haemopoietic islands, has been found.     

Homing and mobilization in the stem cell niche.

All mature blood cells are derived from the haemopoietic stem cell (HSC). In common with all other haemopoietic cells, stem cells are mobile, and it is this property of mobility that has allowed bone marrow transplantation to become a routine clinical option. Successful transplantation requires haemopoietic stem cells to home to the bone marrow, leave the peripheral circulation and become stabilized in regulatory niches in the extravascular space of the bone marrow cavity. This homing and tethering process is reversible - haemopoietic stem cells can be released from their bone marrow tethering through changes in molecular interactions, which are also important in homing following transplantation. The molecular mechanisms regulating this two-way flow of stem cells are beginning to be elucidated, and much recent data has emerged that sheds light on the processes and molecules involved in these complex physiological events. This article reviews current knowledge of the adhesive, homing and proliferative influences acting on HSCs and progenitor cells.     

Regulation of haemopoietic stem-cell proliferation in mice carrying the Slj allele

We investigated a haemopoietic stromal defect, in mice heterozygous for the Slj allele, during haemopoietic stress induced by treatment with bacterial lipopolysaccharides (LPS) or lethal total body irradiation (TBI) and bone-marrow cell (BMC) reconstitution. Both treatments resulted in a comparable haemopoietic stem cell (CFU-s) proliferation in Slj/+ and +/+ haemopoietic organs. There was no difference in committed haemopoietic progenitor cell (BFU-e and CFU-G/M) kinetics after TBI and +/+ bone-marrow transplantation in Slj/+ and +/+ mice. The Slj/+ mice were deficient in their ability to support macroscopic spleen colony formation (65% of +/+ controls) as measured at 7 and 10 days after BMC transplantation. However, the Slj/+ spleen colonies contained the same number of BFU-E and CFU-G/M as colonies from +/+ spleens, while their CFU-s content was increased. On day 10 post-transplantation, the macroscopic 'missing' colonies could be detected at the microscopic level. These small colonies contained far fewer CFU-s than the macroscopic detectable colonies. Analysis of CFU-s proliferation-inducing activities in control and post-LPS sera revealed that Slj/+ mice are normal in their ability to produce and to respond to humoral stem-cell regulators. We postulate that Slj/+ mice have a normal number of splenic stromal 'niches' for colony formation. However, 35% of these niches is defective in its proliferative support.     

SELF-MAINTENANCE ABILITY AND KINETICS OF HAEMOPOIETIC STROMA PRECURSORS

The use of repeated femoral curettages and repeated passages of ectopic haemopoietic foci has demonstrated the capacity of stromal precursor cells for repeated formation of haemopoietic microenvironment. During this process the stromal precursors undergo no less than ten to twelve mitoses. Precursors of bone marrow stroma proliferating slowly, if at all, in normal mice are triggered into cell cycle, as revealed by suicide methods, during formation of the ectopic haemopoietic focus.     

Effect of erythrocyte degradation products on the migration of hematopoietic stem cells in lethally irradiated mice

In experiments on CBA mice it was shown that erythrocytes administered at the stage of prehemolysis or the stromal fraction of erythrolysate caused an additional increase in the haemopoietic stem cell migration which had been intensified by hemorrhage or hypoxic hypoxia.