Haemopoietic centres in the developing angelfish,Pterophyllum scalare (cuvier and valenciennes)

Summary The first haemopoietic centres in the embryo ofPterophyllum scalare are found in the blood islands of the yolk sac. These results are in contrast to the classical theory of blood formation in teleosts, which maintains that the first blood formation occurs intraembryonically, in the so-called intermediate cell mass of Oellacher. InPterophyllum, the intermediate cell mass forms only the axial blood vessels. Haemopoiesis in the post-embryo is carried out by the pronephros. This organ remains haemopoietic to the adult stage. In the adult, the pronephric tubules are degenerated; the organ is filled with haemopoietic tissue and also contains strands of adrenal tissue. The adult kidney (mesonephros) is also haemopoietic, though to a much lesser degree than the pronephros.The blood islands in the yolk sac form only stem cells (haemocytoblasts) and proerythroblasts. Released into the circulation, they differentiate and mature into round, disc-like erythrocytes (erythrocytes-E). Erythropoiesis in the pronephros produces elliptical erythrocytes (erythrocytes-ImA). Thus for the latter part of the postembryonic phase, until complete absorption of the yolk, there is a mixed erythrocyte population in circulation. During metamorphosis into the laterally-compressed adult, the adult type of erythrocyte (erythrocyte-A) makes its first appearance. Leucocytes and thrombocytes appear much later in development than the red blood cells. They are formed in the pronephros and are seen in circulation only after the yolk has been absorbed.     

A mathematical model of haemopoiesis as exemplified by CD34 cell mobilization into the peripheral blood

A mathematical model for the kinetics of haemopoietic cells, including CD34+cells, is proposed. This minimal model reflects the known kinetics of haemopoietic progenitor cells, including peripheral blood CD34+ cells, white blood cells and platelets, in the presence of granulocyte colony-stimulating factor. Reproducing known perturbations within this system, subjected to granulocyte colony-stimulating factor treatment and apheresis of peripheral blood progenitor cells (CD34+ cells) in healthy individuals allows validation of the model. Predictions are made with this model for reducing the length of time with neutropenia after high-dose chemotherapy. Results based on this model indicate that myelosuppressive treatment together with infusion of CD34+ peripheral blood progenitor cells favours a faster recovery of the haemopoietic system than with granulocyte colony-stimulating factor alone. Additionally, it predicts that infusion of white blood cells and platelets can relieve the symptoms of neutropenia and thrombocytopenia, respectively, without drastically hindering the haemopoietic recovery period after high dose chemotherapy.     

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.     

Age dependence of the number of the stem cells in haemopoietic tissues of rats.

The number and concentration of haemopoietic stem cells in the femoral bone marrow and spleen of Wistar rats of different ages were investigated. Stem cells were assayed by the spleen colony technique in irradiated rat recipients. The ability of the recipient spleen to harvest transplanted tissue as a macroscopic colony was found to be dependent on the recipient's age. Changes with senescence were observed also in the concentration and the size of the stem cell compartment both in the marrow and spleen. No differences were demonstrated in the seeding of transplanted colony-forming units into the spleen of recipients of 1 and 4 months of age. A rats-mice strain difference in the effect of senescence on the haemopoietic stem cells is discussed.     

Interstitial pneumonia as a cause of early mortality in allogeneic bone marrow transplantation: the Viennese experience

A uniquely low incidence and death rate of interstitial pneumonia after allogeneic bone marrow transplantation for haemopoietic malignancy is described. Deduced from the comparison with results from a multicenter study, we conclude, that a) reduction of the dose rate to less than 5 rad/min, b) exclusion of CMV pos platelet donors and c) application of a CMV hyperimmune globulin are effectful means to reduce this most often deathly complication after BMT for haemopoietic malignancy.     

The effect of diucifon on the hematopoietic and immune systems in normal and irradiated organisms

It was shown that irradiation of mice with the dose of 4 Gy affected the immune and haemopoietic systems. Diucyphone injected on days 6-8 after irradiation favoured the production of antibodies in the spleen, increased the yield of exogenous splenic colonies and corrected differentiation of the haemopoietic stem cells. In the normal body, diucyphone decreased the colony-forming activity and did not change the haemopoietic stem cell differentiation.     

Investigations on erythropoiesis in newborn rats. Dependence of erythropoiesis in newborn rats on the intensity of the haemopoietic processes in the lactating mothers.

The intensity of haemopoietic processes was investigated in 7, 9, 11, 14 and 19-day-old suckling rats in relation to the intensity of these processes in their mothers. The rate of the haemopoietic processes in newborn rats was determined on the basis of 59Fe incorporation into the blood and haemopoietic organs. The activity of the erythropoietic system in lactating rat females was stimulated by haemorrhage and inhibited by erythrocyte transfusion. Anaemization of lactating rats by haemorrhage did not stimulate erythropoiesis in the suckling rats. Posttransfusion polycythaemia in the lactating mothers inhibited erythropoiesis in the suckling rats beginning with the 9th day of life. This phenomenon became more pronounced with the age of the rats.     

Evaluation of the level and radiosensitivity of the hematopoietic stem cell pool in man by the number of endocolonies of undifferentiated cells forming against a background of post-radiation bone marrow aplasia

The value and radiosensitivity of human haemopoietic stem pool may be assessed by the number of colonies of nondifferentiated cells (CFUnc) formed in situ during regeneration of the haemopoietic organ from the postirradiation aplasia. The time required for doubling the population, that constitutes nondifferentiated cell endocolonies, was reduced as the radiation dose increased.     

Radiation injury of hemopoiesis in alpine conditions depending upon the duration of adaptation

A study was made of the disturbance of haemopoiesis in the small laboratory animals and dogs kept in Alpine conditions (3200 m) and exposed to ionizing radiation on days 3, 15, 22, 25 and 33 of adaptation. The radiation damage to haemopoiesis in Alpine conditions was shown to decrease at the beginning of the adaptation due to the intensification of the regenerating processes, which was manifested by the increase in the rate of DNA synthesis in the haemopoietic organs, and activation of erythropoiesis, myelopoiesis and lymphopoiesis. Later (after 30-35 days), a 2-4-fold increase was noted in the number of haemopoietic stem cells which improved the compensatory potency of the tissue under study and increased the total resistance of the organism.     

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.     

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.     

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.     

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.     

Function of the hematopoietic system in irradiated animals prophylactically administered 2-amino-2-thiazoline

The effect of 2-amino-2-thiazoline (2-AT) on radiosensitivity of mice, their haemopoietic system status, and GFUc has been studied. 2-AT was shown to contribute to the survival of an increased number of haemopoietic stem cells, earlier recovery of bone marrow cellularity, and normalization of the spleen weight.     

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 haemopoiesis

Many of the haemopoietic cell growth factors have now been purified to homogeneity and their structural genes cloned. Methods are also now available for obtaining pure populations of haemopoietic cells. The use of such cells, in combination with pure growth factors, has provided intriguing information about the biological activities and mode of action of the factors in faciliating survival, proliferation and differentiation of the haemopoietic cells.     

Role of phosphofructokinase during trout haemopoiesis: physiological regulation of glycolysis

1. The regulatory properties of phosphofructokinase (PFK) has been investigated in two cellular population representatives of trout haemopoiesis; haemopoietic cells (capable of replication and differentiation) and erythrocytes (highly specialized cells). 2. The intracellular levels of substrates and effectors have been quantified and their effect on PFK activity determined. 3. Fructose 1,6-bisphosphate anc cyclic AMP show a higher activation of the PFK from haemopoietic cells than the enzyme from erythrocytes. 4. AMP and phosphoenolpyruvate act as activators of the haemopoietic cell PFK while for erythrocytes PFK, AMP is an inhibitor and phosphoenolpyruvate does not display any effect. 5. Citrate inhibits PFK activity from haemopoietic cells but was not assayed in erythrocytes since it was not detected in these cells. 6. The differences in PFK regulation in both cellular populations may be attributed to the intracellular levels of the effectors and/or different isoenzymatic patterns. 7. The different regulation of PFK together with the higher enzymatic activity of PFK and pyruvate kinase from haemopoietic cells are related to the higher glycolytic flux that exhibits the haemopoietic cells. 8. The results shown in this investigation allow us to conclude that PFK has a specific role depending on the energetic requirements of the cellular population in which the enzyme is present. 9. The requirements are related to the physiological function of each type of cell.     

Macrophages in haemopoietic and other tissues of the developing mouse detected by the monoclonal antibody F4/80.

Macrophages are widely distributed in lymphohaemopoietic and other tissues of the normal and diseased adult, where they play an important role in host defence and repair. Although the development of haemopoiesis has been well studied in several species, the ontogeny of the mononuclear phagocyte system remains poorly understood. We have used a highly specific mAb, F4/80, to examine the distribution of mature macrophages in the developing mouse, with special reference to their presence in the haemopoietic microenvironment. Monocytes and macrophages were first seen in embryos on day 10 in the yolk sac and liver as well as in mesenchyme. In liver, spleen and bone marrow, there was expansion of this population associated with the initiation of haemopoiesis on days 11, 15 and 17, respectively. Macrophages in these sites formed part of the haemopoietic stroma and their extensively spread plasma membrane processes could be seen making intimate contacts with clusters of differentiating haemopoietic cells. F4/80+ cells were widely dispersed in undifferentiated mesenchymal tissue in organs such as lung, kidney and gut. Numbers of F4/80-labelled cells increased concomitantly with organ growth and local mitoses were evident, as well as actively phagocytic macrophages. Our studies establish that macrophages are among the earliest haemopoietic cells to be produced during development and that they are relatively abundant in fetal tissues in the absence of overt inflammatory stimuli. Their distribution is correlated with the sequential migration of haemopoiesis and they constitute a prominent component of the stroma in fetal liver, spleen red pulp and bone marrow. Apart from a role in haemopoietic cellular interactions, their highly developed endocytic and biosynthetic activities suggest that macrophages contribute major undefined functions during growth, turnover and modelling of fetal tissues.