Composition and synthesis of glycolipids in megakaryocytes and platelets: differences in synthesis in megakaryocytes at different stages of maturation

The composition and synthesis of megakaryocyte and platelet glycolipids were compared since these lipids are thought to be important for biologic activities such as adhesion and maturation. Highly purified guinea pig megakaryocytes at different stages of maturation and platelets were studied. Glycolipids and gangliosides were extracted, separated by thin-layer chromatography, and the carbohydrate content was analyzed by gas-liquid chromatography (GLC). Synthesis of ceramides and glycolipids was determined by the incubation of megakaryocytes with [14C]acetate, [3H]palmitic acid, and [3H]galactose. A major neutral glycolipid present in guinea pig megakaryocytes and platelets was identified as asialoGM2 by selective enzymatic hydrolysis with beta-N-acetylhexosaminidase, alpha-galactosidase and endo-beta-galactosidase, and carbohydrate analysis by GLC. Trace amounts of asialoGM1 were detected immunologically. The cells also contained glucosyl ceramide and lactosyl ceramide. Several ganglosides were detected of which one was identified as GM1 by its reaction with the beta-subunit of cholera toxin and by the identification of an asialoGM1 core with anti-asialoGM1 antibody after desialylation. The synthesis of ceramides from palmitic acid and acetate was 5 and 10 times greater, respectively, in megakaryocytes than in platelets. Ceramide and glycolipid synthesis from palmitic acid occurred primarily in immature megakaryocytes while synthesis from acetate occurred primarily in more mature megakaryocytes. The glycosylation of ceramides from galactose was 42 times greater in megakaryocytes than in platelets. Thus, ceramides and glycolipids are primarily synthesized in megakaryocytes, but platelets retain the capacity to synthesize significant amounts of free ceramides. The glycosylation of free ceramides occurs almost exclusively in megakaryocytes and only in trace amounts in platelets. These data indicate that megakaryocytes determine the composition of glycolipids in platelets and that there is considerable compartmentalization of glycolipid synthesis and membrane assembly at various stages of megakaryocytes development.     

Elutriation for isolation of megakaryocytes

Successful isolation of guinea pig megakaryocytes in large numbers was first achieved with a combination of techniques, taking sequential advantage of the low relative densities and large diameters of most megakaryocytes. Several laboratories have made minor improvements, but this approach retains the disadvantage of losing a significant fraction of the megakaryocyte population, the small immature ones. Counterflow centrifugal elutriation has been shown to eject cells from a chamber progressively, according to their sizes. Because almost all the megakaryocytes are bigger than the other marrow cells, the megakaryocytes can be retained while rejecting the contaminants. With this technology, yields of 1.4-2.0 x 10(6) megakaryocytes from one guinea pig are routine, recoveries have been 93%-94% of the input number of megakaryocytes, and final purities now average 72%. A split-specimen comparison with our previous method found elutriation to provide much greater yield and recovery with at least as great a purification as the density-velocity combination. This new technique was easily adapted to isolation of megakaryocytes in single aspirates from normal human marrow. Fifty-fold purification with near total recovery and a yield of 27,000 megakaryocytes per donor allows easy and reliable cytologic studies. Elutriation appears to be the current method of choice for isolation of megakaryocytes.     

Suppression and acceleration of DNA synthesis in megakaryocytes after partial hepatectomy

3H-thymidine labelling indices of megakaryocytes were determined in the spleen and bone marrow of normal, sham-operated and partially hepatectomized rats. Compared with controls, the labelling indices were much lower in megakaryocytes but much higher in other cells such as erythroid cells or proliferating duodenal mucosal cells when measured in rats from 12 to 36 h after partial hepatectomy. From 48 to 72 h after hepatectomy the labelling indices of megakaryocytes became higher than control values. On the other hand the labelling indices of megakaryocytes from 12 to 36 h after sham operation were higher than controls. The accelerated DNA synthesis of megakaryocytes after sham operation was considered to reflect the additional DNA synthesis in this cell line which leads to an increase of the average ploidy level. The initial decrease in labelling indices of megakaryocytes after partial hepatectomy did not occur if serum from normal or thrombocytopenic rats was injected. These findings suggest that the liver may produce a humoral factor which influences the so-called endomitosis of megakaryocytes.     

Isolation of intact megakaryocytes from guinea pig femoral marrow. Successful harvest made possible with inhibitions of platelet aggregation; enrichment achieved with a two-step separation technique

Methods have been devised to harvest megakaryocytes from guinea pig femoral marrow and to isolate them in high yield. When marrow tissue was disaggregated the megakaryocytes underwent degenerative changes characterized by the loss of cytoplasmic granules and alterations in membrane topography, similar to the changes seen in aggregating platelets. These morphologic changes were interpreted to mean that megakaryocytes possessed functional attributes of platelets. The use of agents which inhibit platelt aggregation (0.38% sodium citrate. 10(-3) M adenosine, and 2 x 10(-3) M theophylline) in a medium free of bivalent cations prevented these changes. This solution resulted in both an excellent morphologic preservation and a significantly increased recovery of megakaryocytes from marrow tissue. A two-step purification of the intact megakaryocytes was carried out on the basis of their low density and large size, with equilibrium density gradient centrifugation followed by velocity sedimentation. This sequence gave approximately a 100-fold enrichment of megakaryocytes, significantly better than that achieved with either method alone. These techniques for harvesting and concentrating megakaryocytes make it possible for the first time to study megakaryocytes in vitro.     

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.     

Effects of gangliosides on cell maturation of murine megakaryocytes in a liquid culture system

Formation of platelet-producing megakaryocytes, the cytoplasm of which showed the terminal stage of cell maturation, heavy granulation and platelet-fields delineated with demarcation membranes, was observed in a short-term culture system, using megakaryocyte-enriched bone marrow cell suspension. Approximately 6-8% of the megakaryocytes changed to the platelet-producing megakaryocytes during 12-hour incubation. In the presence of inhibitors of energy metabolism, formation of the platelet-producing megakaryocytes was inhibited, suggesting that the process is dependent on energy producing systems. Ganglioside GD1a increased both the number of total megakaryocytes and the ratio of the platelet-producing megakaryocytes to total megakaryocytes, while GM1 did not influence the number of total megakaryocytes, but increased the ratio. Gangliosides GM2, GM3 and GD1b showed little effect on either the number of total megakaryocytes or the ratio. The results suggest that ganglioside GD1a stimulates at least two steps of megakaryocyte maturation, the change of megakaryocytic progenitors to megakaryocytes and the subsequent maturation of megakaryocytes to the platelet-producing megakaryocytes, while GM1 stimulates only the latter step of the maturation.     

The effect of viruses on megakaryocytes in vitro (author's transl)

Bone marrow suspensions from adolescent rats contain 0.3% megakaryocytes; this rate decreases to almost zero within 72--96 h cultivation in vitro in Leighton tubes because of thrombocytopoesis. Such cultures were inoculated immediately after seeding with different viruses in high multiplicity. After infection with herpes simplex virus type 1 or adenovirus type 2, no deviation of the number and morphology of the megakaryocytes was seen when compared with control cultures. However, after infection with vaccinia virus and, still more marked, with Newcastle disease virus, morphological alterations and interference with thrombocytopoesis were seen. Furthermore, a considerable portion of the altered megakaryocytes persisted for 72--96 h. Finally, the cytoplasm of the megakaryocytes after infection with vaccinia virus or NDV, but not with HSV 1 or adenovirus 2, showed a specific immunofluorescence with antiviral antisera, which indicates a direct cellular involvement and multiplication of vaccinia virus and NDV in megakaryocytes.     

Wistar Furth Rat Megakaryocytes Lack Dense Compartments and Intercellular Plaques,Membranous Structures Rich in Cytoskeletal Proteins

Wistar Furth (WF) rats have an abnormal thrombopoietic phenotype with morphologically aberrant megakaryocytes, larger than normal mean platelet volume, and platelet alpha-granule protein deficiency. Here, ultrastructural comparisons of WF rat megakaryocytes to those of rats (Wistar) with normal platelet formation during stimulated megakaryocytopoiesis following 5-fluorouracil administration, have revealed a previously unrecognized membrane structure in normal rat megakaryocytes, and two additional abnormalities in WF megakaryocytes. The novel structures were zones of electron density on the cytoplasmic face of apposed plasma membranes of adjoining normal megakaryocytes. These modified focal adhesion-type contacts were distributed at intervals between adjacent megakaryocytes, and were spaced by deposits of extracellular material. These structures also were present between apposed plasma membranes of Wistar rat megakaryocytes in unperturbed marrows, but were absent between megakaryocytes of WF rats. The second WF rat megakaryocyte abnormality is the absence of cytoplasmic dense compartments, another specialized membranous structure that is continuous with the megakaryocyte demarcation membrane system. Both the intercellular plaques and dense compartments of Wistar rat megakaryocytes were found to be rich in cytoskeletal proteins including actin, α-actinin, talin, and vinculin as indicated by ultrastructural immunogold labeling. We hypothesize that an abnormality in cytoskeletal protein function may be responsible for the lack of these structures in the WF rat.     

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.     

Lycramine brilliant blue JL: a new stain for human megakaryocytes

Using the acrylic textile dye Lycramine brilliant blue JL, mature and immature megakaryocytes from human bone marrow specimens stained metachromatically bright lavender. This coloration was not observed in other types of bone marrow cells. After digestion with either diastase or ribonuclease, subsequent staining of marrow specimens did not reveal a significant diminution of the intensity of staining of megakaryocytes. However, after incubation with hyaluronidase followed by staining with Lycramine brilliant blue JL, staining of megakaryocyte cytoplasm was either imperceptible or very pale blue. Accordingly, at least one of the substances responsible for the staining reaction is acid mucopolysaccharide in the cytoplasm of megakaryocytes. With further experience and comparison with established immunologic and cytochemical techniques, staining of megakaryocytes with Lycramine brilliant blue JL may be a useful addition to the cytochemistry of blood and bone marrow cells.     

Lycramine Brilliant Blue Jl: A New Stain for Human Megakaryocytes

Using the acrylic textile dye Lycramine brilliant blue JL, mature and immature megakaryocytes from human bone marrow specimens stained metachromatically bright lavender. This coloration was not observed in other types of bone marrow cells. After digestion with either diastase or ribonuclease, subsequent staining of marrow specimens did not reveal a significant diminution of the intensity of staining of megakaryocytes. However, after incubation with hyaluronidase followed by staining with Lycramine brilliant blue JL, staining of megakaryocyte ctyoplasm was either imperceptible or very pale blue. Accordingly, at least one of the substances responsible for the staining reaction is acid mucopolysaccharide in the cytoplasm of megakaryocytes. With further experience and comparison with established immunologic and cytochemical techniques, staining of megakaryocytes with Lycramine brilliant blue JL may be a useful addition to the cytochemistry of blood and bone marrow cells.     

Functionally abnormal stromal cells and megakaryocyte size, ploidy, and ultrastructure in Sl/Sld mice

The first goal of the present studies was to determine if Sl/Sld megakaryocytes have features in common with the macrocytic megakaryocytes that genetically normal mice produce in response to acute platelet depletion. The second was to test the hypothesis that megakaryocyte abnormalities in Sl/Sld mice are due to genetically determined hemopoietic stromal cell abnormalities. Sizes and ploidies of mature Sl/Sld megakaryocytes were measured. Macrocytosis and a shift to higher ploidy values were found compared with normal. Within ploidy groups 16N-64N, Sl/Sld megakaryocytes were larger than normal megakaryocytes of the same ploidy. Transmission electron microscopy revealed that Sl/Sld megakaryocyte nuclei contain more and larger nucleoli, and the chromatin was more dispersed than in normal megakaryocyte nuclei of comparable maturity. Asynchronous megakaryocyte cytoplasmic maturation was found. Sl/Sld macrophages were also ultrastructurally abnormal. Megakaryocytic macrocytosis was reproduced in long-term bone marrow cultures in which the adherent layer was formed by Sl/Sld cells. It was the same if cultures were recharged with Sl/Sld or +/+ hemopoietic cells. Previously reported ambiguities in mixed cell cultures were avoided by recharging the adherent layers with only a million cells. These results were correlated with previously published observations. Sl/Sld megakaryocytes have features in common with megakaryocytes from acutely thrombocytopenic animals. One feature, macrocytosis, appears to be due to abnormal Sl/Sld stromal cells that are reproduced as adherent layer cells in long-term cultures. The responsible stromal cells in Sl/Sld mice may be counterparts of megakaryocytopoietic regulatory cells in the marrow stroma of normal animals.     

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.     

Location of sites of dopamine storage in megakaryocytes by autoradiography

We have used quantitative electron microscope autoradiography to study the subcellular sites of 3H-dopamine uptake in mouse megakaryocytes after a single intraperitoneal injection. Autoradiographic grains were found to be associated almost exclusively with the vesicles of precursors of monoamine-storage organelles. The labeling intensity (radioactivity) of the demarcation membrane system which is continuous with the plasmalemma was also significantly greater than would be expected. On the other hand, radioactivity associated with the remaining sites in the cytoplasm was not significantly different from that expected of a random distribution. In order to compare 3H-dopamine uptake during cell maturation, light microscope autoradiographic studies were also done. Immature megakaryocytes were labeled slightly, but the number of silver grains increased significantly in maturing cells. Mature megakaryocytes were 2.7 times more radioactive than the maturing cells. Our results suggest that the megakaryocytes were able to accumulate dopamine from the early stages of cell maturation and to store dopamine in precursors of monoamine-storage organelles.     

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。     

Lipid composition and metabolism in megakaryocytes at different stages of maturation

The lipid composition and metabolism of isolated guinea pig megakaryocyte subgroups at various stages of maturation were investigated. Three groups were studied: 1) 67% of megakaryocytes in Group A were immature; 2) Group B was heterogeneous and contained both immature and mature subgroups of megakaryocytes; 3) 92% of megakaryocytes in Group C were mature. Lipid composition was determined by thin-layer chromatography, lipid-phosphorus, and gas-liquid chromatography. Cholesterol, ceramide, and de novo fatty acid synthesis were evaluated with [14C]acetate. [14C]Glycerol was used to assess de novo phospholipid synthesis. 14C-Labeled fatty acids were used to evaluate fatty acid uptake. The phospholipid and cholesterol content was found to be four times greater in mature megakaryocytes than that in immature megakaryocytes, which paralleled the protein content and volume of mature and immature cells. The cholesterol-phospholipid ratio was similar and there were no differences in the phospholipid species in the three groups. Phospholipid and cholesterol synthesis were established in immature megakaryocytes and persisted at about the same level in mature megakaryocytes. The uptake of arachidonic and palmitic acids also occurred primarily in immature cells, while the de novo synthesis of palmitic acid occurs predominantly in mature megakaryocytes. There was an inverse relationship between the uptake of exogenous palmitic acid and fatty acid synthesis, but the uptake of palmitic acid primarily inhibited fatty acid synthesis in mature megakaryocytes. There were differences in the acylation of phospholipid species with arachidonic acid in megakaryocytes at different stages of maturation since the acylation of phosphatidylcholine occurred primarily in immature megakaryocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

RhoA Is Essential for Maintaining Normal Megakaryocyte Ploidy and Platelet Generation

RhoA plays a multifaceted role in platelet biology. During platelet development, RhoA has been proposed to regulate endomitosis, proplatelet formation, and platelet release, in addition to having a role in platelet activation. These processes were previously studied using pharmacological inhibitors in vitro, which have potential drawbacks, such as non-specific inhibition or incomplete disruption of the intended target proteins. Therefore, we developed a conditional knockout mouse model utilizing the CRE-LOX strategy to ablate RhoA, specifically in megakaryocytes and in platelets to determine its role in platelet development. We demonstrated that deleting RhoA in megakaryocytes in vivo resulted in significant macrothrombocytopenia. RhoA-null megakaryocytes were larger, had higher mean ploidy, and exhibited stiff membranes with micropipette aspiration. However, in contrast to the results observed in experiments relying upon pharmacologic inhibitors, we did not observe any defects in proplatelet formation in megakaryocytes lacking RhoA. Infused RhoA-null megakaryocytes rapidly released platelets, but platelet levels rapidly plummeted within several hours. Our evidence supports the hypothesis that changes in membrane rheology caused infused RhoA-null megakaryocytes to prematurely release aberrant platelets that were unstable. These platelets were cleared quickly from circulation, which led to the macrothrombocytopenia. These observations demonstrate that RhoA is critical for maintaining normal megakaryocyte development and the production of normal platelets.