Regulation of thrombocytopoiesis studied by a mathematical model

A mathematical model of thrombocytopoiesis is proposed which accounts for the recent data on its regulation. It is shown that the compensatory response of the system to a decrease in the level of thrombocytes in the blood is controlled by the total amount of thrombocytes and megakaryocytes. The proliferation intensity of megakaryocytes and the total number of thrombocytes reveal, respectively, a lineary and a logarithmical dependence on the total number of thrombocytes and megakaryocytes. The limits of the post-transfusion level of thrombocytes are defined, within which the thrombocytopoiesis is controlled only by the number of thrombocytes. The values of parameters characterizing the behaviour of the thrombocytopoiesis system are calculated.     

Megakaryocytopoiesis studied in a mathematical model. 4. Regulation of cell flow in a transit population

The role of cells capable of formation of megakaryocytic colonies (CFUm) in regulation of thrombocytopoiesis was studied using a simulation model of megakaryocytopoiesis. The CFUm were shown to be the least differentiated cells involved in regulation of megakaryocytopoiesis in mice upon immune thrombocytopenia and after intravenous injection of hydroxyurea. A correlation was found between the CFUm population productivity and the number of cells in a transit population of the megakaryocytic line which makes it possible to reproduce experimental kinetics in the model. The duration of cell development from CFUm to megakaryocytes is about 3 days.     

Capacity of bone marrow cells to restore thrombocytopoiesis in lethally irradiated animals

A study was made of the kinetics of thrombocytopoiesis restoration in lethally irradiated mice after transplantation to them of the donor marrow cells. In the initial period, the thrombocytopoiesis restoration is provided by transite cells-precursors of megakaryocytes present in the transplanted bone marrow; the subsequent restoration is due to cells of the self-maintaining population. The level of restoration does not correlate with the number of polypotent cells that form macrocolonies in the spleen of irradiated recipients.     

Regulation of murine megakaryocyte size and ploidy by non-platelet-dependent mechanisms in radiation-induced megakaryocytopenia

Megakaryocytic macrocytosis was evaluated in mice after irradiation with 6.5 Gy 60Co gamma rays. During the second and third months after sublethal irradiation, one or more of the following abnormalities of thrombocytopoiesis was present: thrombocytopenia, megakaryocytopenia, macromegakaryocytosis, a shift to higher ploidies, and enlargement of cells within ploidy groups. After transfusion-induced thrombocytosis, reductions in megakaryocyte size were delayed or absent relative to non-irradiated mice, and there was more of a tendency to shift to lower values for megakaryocyte ploidy. Mice with radiation-induced megakaryocytopenia failed to show rebound thrombocytosis during recovery from immunothrombocytopenia, in spite of further increases in megakaryocyte size and ploidy. The findings support the hypotheses that numbers of megakaryocytes may influence the regulation of megakaryocytopoiesis even when there is an excess of platelets and that ploidy distribution is not the sole determinant of the average size of a population of megakaryocytes. After irradiation, persistent megakaryocytopenia may not severely affect platelet production under steady-state conditions, but the ability of the marrow to respond to homeostatic regulation is compromised.     

Human mesenchymal stem cells support megakaryocyte and pro-platelet formation from CD34(+) hematopoietic progenitor cells

Megakaryocytopoiesis and thrombocytopoiesis result from the interactions between hematopoietic progenitor cells, humoral factors, and marrow stromal cells derived from mesenchymal stem cells (MSCs) or MSCs directly. MSCs are self-renewing marrow cells that provide progenitors for osteoblasts, adipocytes, chondrocytes, myocytes, and marrow stromal cells. MSCs are isolated from bone marrow aspirates and are expanded in adherent cell culture using an optimized media preparation. Culture-expanded human MSCs (hMSCs) express a variety of hematopoietic cytokines and growth factors and maintain long-term culture-initiating cells in long-term marrow culture with CD34(+) hematopoietic progenitor cells. Two lines of evidence suggest that hMSCs function in megakaryocyte development. First, hMSCs express messenger RNA for thrombopoietin, a primary regulator for megakaryocytopoiesis and thrombocytopoiesis. Second, adherent hMSC colonies in primary culture are often associated with hematopoietic cell clusters containing CD41(+) megakaryocytes. The physical association between hMSCs and megakaryocytes in marrow was confirmed by experiments in which hMSCs were copurified by immunoselection using an anti-CD41 antibody. To determine whether hMSCs can support megakaryocyte and platelet formation in vitro, we established a coculture system of hMSCs and CD34(+) cells in serum-free media without exogenous cytokines. These cocultures produced clusters of hematopoietic cells atop adherent MSCs. After 7 days, CD41(+) megakaryocyte clusters and pro-platelet networks were observed with pro-platelets increasing in the next 2 weeks. CD41(+) platelets were found in culture medium and expressed CD62P after thrombin treatment. These results suggest that MSCs residing within the megakaryocytic microenvironment in bone marrow provide key signals to stimulate megakaryocyte and platelet production from CD34(+) hematopoietic cells.     

Emperipolesis and interrelations of megakaryocytes and neutrophilic granulocytes in the bone marrow of healthy dogs

Emperipolesis is an ability of one cell to penetrate into cytoplasm of another cell and to stay there for some time, or to pass through it. Unlike a common phagocytosis, not a cell interacting is damaged. Penetration of neutrophilic granulocytes into cytoplasm of megakaryocytes is also considered as emperipolesis, that is revealed in the bone marrow of healthy persons. Its occurrence becomes greater at various pathological states of tumorous and non-tumorous etiology. Histological investigation of the bone marrow of the rib, breast bone, vertebral body and iliac bone crest, performed in 10 healthy dogs makes it possible to state, that there are possible specific interrelations between megakaryocytes and neutrophilic granulocytes, that terminate in death of the former. Therefore, the phenomenon observed cannot be identified with emperipolesis. In this case we, evidently, deal with a morphological demonstration of cell cytotoxicity, when neutrophils, being killers, act as effector-cells, and megakaryocytes - as target-cells. Cell cytotoxicity is a natural phenomenon, that under certain physiological conditions is evidently connected with thrombocytopoiesis.     

Does autoregulation of megakaryocytopoiesis occur?

Although a major regulator of thrombocytopoiesis is the number of circulating platelets, several observations suggest that independent alternative regulatory mechanisms may exist. In some situations there is a curious association of megakaryocytopenia and megakarocytic macrocytosis in spite of normal platelet counts. If macrocytosis is considered as a sign of stimulation, this association suggests a cause and effect relationship between decreased numbers and increased size of megakaryocytes. This thesis was tested by examining the delayed effects of sublethal irradiation and the acute effects of hydroxyurea in mice. It was found that megakaryocytopenia and macromegakaryocytosis occurred together and that platelets counts were either normal or only slightly reduced. Therefore it was concluded that normal numbers of platelets could be produced by decreased numbers of megakaryocytes. Megakaryocytopenia appeared to be compensated, in part, by increased size of megakaryocytes, but the mechanism by which this occurred has not been elucidated. It is postulated that a reduction in the number of cells of the megakaryocytic system is sensed by a homeostatic mechanism that then acts to stimulate the cells that are present. This stimulation may then be manifested as macrocytosis of megakaryocytes.     

人类胚胎期和成年期巨核细胞的分子特征比较

为探究人类不同发育时期巨核细胞的分子特征,基于人类胚胎期卵黄囊、胎肝和成年骨髓巨核细胞的单细胞转录组测序数据,从分子特征、基因调控网络等方面分别对其分子差异进行生物信息学分析。结果表明,胚胎期巨核细胞具有较强的增殖特征,高表达细胞增殖相关的转录因子;而成年期巨核细胞具有较强的血小板生成特征,高表达与巨核细胞分化成熟相关的转录因子。研究结果为研究不同发育阶段巨核细胞及其子代血小板的功能差异提供了理论依据。     

Thyroxine suppresses thrombocytopoiesis and stimulates erythropoiesis in mice.

Thyroxine has been shown in vitro to stimulate erythropoiesis by two mechanisms: a direct, beta 2-adrenergic receptor-mediated stimulation of red cell precursors, and an indirect, erythropoietin-mediated mechanism. Clinical reports have suggested that excess thyroxine also exerts depressive effects on thrombocytopoiesis, but the most sensitive methods of assessing platelet production, i.e., percentage of 35S incorporation into platelets and determination of megakaryocyte size and number, are not appropriate for analysis of platelet production in human patients. The purpose of this study was to use a mouse model to investigate the effects of the hyperthyroid state on erythropoiesis and thrombocytopoiesis, and to assess in vivo the two mechanisms by which thyroxine has been described to stimulate erythropoiesis in vitro. We found that thyroxine administration significantly depressed platelet production and stimulated erythropoiesis in mice. Both the D- and L-isomers of thyroxine in appropriate doses produced this depression of thrombocytopoiesis, and the effect was dose dependent for both isomers. Daily administration of thyroxine:increased blood volume; decreased the peripheral platelet count, total circulating platelet count and mass, percentage of 35S incorporation into platelets, and megakaryocyte number and size; and concurrently increased indices of red cell production (packed cell volume, red blood cell count, total circulating red blood cell count and mass, and reticulocyte count). Additionally, propranolol, a nonspecific beta-blocker, partially reversed the suppression of platelet production by L-thyroxine, lending credence to the assertion that the direct, beta 2-adrenergic receptor-mediated stimulation of the erythroid cell line by thyroxine reported to exist in vitro may also be important in vivo.     

Uptake of 3H-dopamine in megakaryocytes and blood platelets measured by quantitative electron-microscope autoradiography

We studied the uptake of dopamine by mature megakaryocytes and blood platelets in mouse spleen after a single intraperitoneal injection of 3H-dopamine. In order to compare the uptake of 3H-dopamine in mature megakaryocytes and blood platelets, we used quantitative autoradiography at the electron-microscope level. Dense accumulations of silver grains were observed on both mature megakaryocytes and blood platelets; all other tissue elements of the spleen exhibited considerably less dense labeling. No significant differences with regard to dopamine uptake were observed in megakaryocytes and blood platelets. This is in contrast to the previous finding of very different patterns of 3H-5-hydroxytryptamine labeling in mature megakaryocytes and blood platelets (Daimon and Uchida 1985). The results of the present study provide new evidence in favor of the hypothesis that the active uptake mechanism of dopamine through the plasma membrane is different from the uptake mechanism of 5-hydroxytryptamine.     

Multiple levels of regulation of megakaryocytopoiesis

A working hypothesis for the regulation of megakaryocytopoiesis is described on the basis of current data. The hypothesis proposes that in vivo megakaryocytes are generated by 1) the expansion of clonable progenitor cells into immature megakaryocytes by locally produced (and regulated) interleukin-3 (IL-3) and 2) the development and maturation of immature megakaryocytes by a dual system; by a lineage specific mechanism involving thrombopoietic stimuli in the steady state and thrombocytopenic conditions, and by a lineage nonspecific mechanism via IL-3 in damaged or reconstituting marrow. The hypothesis predicts that if IL-3 is a significant in vivo regulator of megakaryocyte formation and development, receptor for IL-3 should be present on megakaryocytes and may be vestigially on platelets. Small but significant levels of 125I IL-3 were found to bind to platelets from normal mice. The level of binding on platelets was found to be enhanced sevenfold from mice that had received high levels of irradiation followed by bone marrow transplantation. This contrasted with a twofold increase in the level of binding to platelets from mice made acutely thrombocytopenic with antiplatelet serum. The data suggest that IL-3 may be involved in the in vivo regulation of murine megakaryocytopoiesis and may be a significant factor in rebound thrombopoiesis following bone marrow damage.     

Uptake of 3H-dopamine in megakaryocytes and blood platelets measured by quantitative electron-microscope autoradiography

Summary We studied the uptake of dopamine by mature megakaryocytes and blood platelets in mouse spleen after a single intraperitoneal injection of ³H-dopamine. In order to compare the uptake of ³H-dopamine in mature megakaryocytes and blood platelets, we used quantitative autoradiography at the electron-microscope level. Dense accumulations of silver grains were observed on both mature megakaryocytes and blood platelets; all other tissue elements of the spleen exhibited considerably less dense labeling. No sigificant differences with regard to dopamine uptake were observed in megakaryocytes and blood platelets. This is in contrast to the previous finding of very different patterns of ³H-5-hydroxytryptamine labeling in mature megakaryocytes and blood platelets (Daimon and Uchida 1985). The results of the present study provide new evidence in favor of the hypothesis that the active uptake mechanism of dopamine through the plasma membrane is different from the uptake mechanism of 5-hydroxytryptamine.     

Modulation of megakaryocyte emperipolesis by phlebotomy: megakaryocytes as a component of marrow-blood barrier

The presence of marrow cells within the cytoplasm of megakaryocytes has been documented and is attributed to the phenomenon of emperipolesis. In a previous study most patients demonstrating this phenomenon had or were suspected of having blood loss. To find out if these are causally related, we induced acute and chronic blood loss in rats and quantitatively measured the emperipolesis index (EI). EI dropped after acute blood loss but rose after chronic blood letting, indicating that blood loss can modulate this phenomenon. In the marrow, megakaryocytes are located preferentially on the abluminal side of sinus endothelium and it is postulated that in the state of heightened demand for cell delivery from marrow into the circulation, some cells take a transmegakaryocytic route to enter the circulation. This concept incorporates megakaryocytes as a component of the marrow-blood barrier.     

Human megakaryocytopoiesis--normal and abnormal.

Regulation of megakaryocyte and platelet production remains poorly understood. In culture system two separate activities are needed for maximum production of megakaryocyte progenitors: promotor of clonal expansion and promoter of maturation, other growth factors and cells also contribute to regulation of megakaryocytopoiesis. Increased proliferation of megakaryocytes is observed in myeloproliferative disorders and idiopathic thrombocytopenic purpura, and decreased proliferation is found in aplastic anaemia and hypomegakaryocytic thrombocytopenia. Dysmegakaryocytopoiesis is present in myelodysplastic syndromes and acute leukaemia, and a proliferation of immature megakaryocytes in acute megakaryoblastic leukaemia. Increased understanding of human megakaryocytopoiesis is beginning to help in rational clinical management.     

Thrombocytopoiesis--analysis by membrane tracer and freeze-fracture studies on fresh human and cultured mouse megakaryocytes

The origin of platelets (Pt) from megakaryocytes (MK) is beyond question, but the mechanism whereby Pts are released from the precursor cell is still debated. A widely-held theory claims that the MK plasma membrane invaginates to form demarcation membranes (DMS), which delineate Pt territories. Accordingly, Pts would be derived mostly from the periphery of the MK, and the MK and Pt plasma membranes would have to be virtually identical. Since, on morphologic grounds, this theory is untenable, several aspects of thrombocytopoiesis were reexamined with the help of membrane tracer and freeze-fracture analyses of freshly-collected human and cultured mouse MK. To our surprise, freeze-cleavage of the MK plasma membrane revealed that the vast majority of intramembranous particles (IMP) remained associated with the protoplasmic leaflet (P face), whereas the partition coefficient of IMPs of the platelet membrane was the reverse. This is the first time that any difference between MK and Pt membranes has been determined. Replicas of freeze-fractured MK that were in the process of thrombocytopoiesis revealed an additional novel phenomenon, i.e., numerous areas of membrane discontinuity that appeared to be related to Pt discharge. When such areas were small, the IMP were lined up along the margin of the crevice. At a later phase, a labyrinth of fenestrations was observed. Thin sections of MK at various stages of differentiation showed that Pt territories were fully demarcated before connections of the DMS with the surface could be found. Therefore, the Pt envelope is probably not derived from invaginations of the MK plasma membrane. When living, MK were incubated with cationic ferritin or peroxidase at 37 degrees C, the tracers entered into the DMS but did not delineate all membranes with which the DMS was in continuity, suggesting the existence of distinctive membrane domains. Interiorization of tracer was not energy-dependent, but arrested at low temperatures. At 4 degrees C the DMS remained empty, unless there was evidence that Pts had been released. In such instances, the tracers outlined infoldings of peripheral cytoplasm that was devoid of organelles. Thus, the majority of Pts seem to originate from the interior of the MK, and the surface membranes of the two cells differ in origin and structure. The observations do not only throw new light on the process of thrombocytopoiesis, but also strengthen the possibility that MKs and Pts may be subject to different stimuli.     

Megakaryocytopoiesis studied in a mathematical model. 3. Regulation of cell differentiation in immune thrombocytopenia

Simulation experiments have shown that just after antiplatelet serum of rabbit blood is introduced into mice the transit time of early proliferating precursors of the megakaryocytes is reduced by about 17 h, the transit time for megakaryoblasts increases, and within 24 h after the treatment the transit time for mature megakaryocytes is reduced b about 17 h. The data obtained confirmed our earlier hypothesis on correlation between the duration of proliferative period and the mean size of megakaryocytes.     

Expression, activation, and subcellular localization of the Rap1 GTPase in cord blood-derived human megakaryocytes

The expression of the small GTPase Rap1 in human megakaryocytes (MKs) differentiated from cord blood (CB)-derived progenitors was investigated. High levels of Rap1 were detected in the majority of mature megakaryocytes independently of days of culture, while a very low percentage of immature megakaryocytes was found to express a small amount of the protein. Rap1 was predominantly detected on internal alpha-granule but not on the plasma membrane. By contrast, CD41 was clearly present on the peripheral plasma membrane, although it also displayed an intracellular localization similar to that of Rap1. Upon thrombin stimulation, both Rap1 and CD41 translocated to the periphery of the cell. At the opposite, RhoA GTPase and glycoprotein Ibalpha were predominantly located at the plasma membrane and did not undergo relocation upon thrombin stimulation. Thrombin induced a dose- and time-dependent activation of Rap1 in mature megakaryocytes. By using a confocal microscopy approach with a specific probe, active Rap1 was detected exclusively at the peripheral plasma membrane. These results demonstrate that expression of Rap1 occurs during maturation rather than differentiation of megakaryocytes from cord blood progenitor cells. Moreover, we demonstrate that thrombin-activated Rap1 is exclusively localized at the peripheral plasma membrane.     

Phospholipid composition of rat megakaryocytes and its rearrangement in platelets

Rat platelets and their megakaryocyte precursors were examined for phospholipid composition. (1) The phospholipid composition of rat megakaryocytes, which were enriched and prepared from bone marrow cells, was almost identical to that of platelets. (2) The subclass composition of choline-containing glycerophospholipids (CGP) of rat megakaryocytes differed significantly from that of platelets: 1-alkenyl-2-acyl glycerophosphocholine (GPC) in megakaryocytes accounted for 29% of the total, whereas that in platelets was only 7%. (3) Rat platelets contained a larger amount of arachidonic acid than megakaryocytes, especially in ethanolamine-containing glycerophospholipids (EGP). (4) [32P]Phosphoric acid was significantly incorporated into megakaryocytes, whereas platelets showed little incorporation. On the other hand, the uptake of [3H]arachidonic acid into platelet phospholipids was about 15-times higher than that observed with megakaryocytes. (5) As reported previously for other blood cells, such as neutrophils and macrophages, the radioactivity of labeled arachidonic acid incorporated into CGP of platelets decreased, whereas that incorporated into EGP increased during a subsequent chase period. Hardly any such change was observed with megakaryocytes. These results suggest that the phospholipid composition of rat platelets is mainly determined at the time of thrombopoiesis, whereas the composition of molecular species is remodeled during circulation after thrombopoiesis.     

Stimulation of megakaryocytic spleen colonies in mice by thrombopoietin.

Kidney cell culture medium that was shown to stimulate thrombocytopoiesis in TSF assay mice was injected into lethally-irradiated, bone marrow transplanted mice. Results showed that the injection of TSF-rich material caused an increase in the number of megakaryocytic colonies when compared to control mice. The numbers of surface colonies and colonies/spleen section were not altered by TSF treatment. Erythroid, granulocytic, and undifferentiated colonies were not elevated by TSF injection. These data support the hypothesis that kidney cells in culture produce a humoral factor that controls the regulation of platelet and megakaryocyte production.