Ultrastructural demonstration of CD36 in the alpha-granule membrane of human platelets and megakaryocytes

CD36 (glycoprotein [GP] IV) is a membrane GP of 88 kD found on monocytes, endothelial cells, and platelets. It may serve as a receptor for collagen and is also able to bind thrombospondin (TSP), because a monoclonal antibody to CD36 inhibits TSP binding to thrombin-stimulated platelets. In the following study, we investigated the subcellular distribution of CD36 within normal resting platelets, thrombin- stimulated platelets, and in cultured megakaryocytes (MK) by an immunogold staining technique and electron microscopy. We used an affinity-purified monospecific polyclonal antibody showing a single major band of precipitation at 88 kD via immunoblot analysis. In normal platelets, ultrastructural observation detected immunolabeling for CD36, homogeneously distributed along the platelet plasma membrane and in the luminal side of the open canalicular system (OCS). Moreover, some labeling was found around the alpha-granules along the inner face of their limiting membrane. An average of 70% of granules were labeled. The granule-associated pool of CD36 was estimated at approximately 25% of the total cell content. To exclude the possibility of a cross- reaction with GPIIb-IIIa, platelets from a patient with type I Glanzmann's thrombasthenia (which completely lack GPIIb-IIIa) were studied and showed a similar subcellular distribution of CD36, including alpha-granule membrane labeling. In activated platelets, CD36 was shown to be redistributed to the OCS and pseudopods of the plasma membrane. Platelets from a patient with the Gray platelet syndrome expressed CD36 on their plasma membrane, and some immunolabeling was also found within small abnormal alpha-granules. In cultured MK, CD36 immunolabeling was detected in the Golgi saccules, associated vesicles, immature alpha-granules, and demarcation membranes. In conclusion, this study shows the existence of a significant intragranular pool of CD36 in platelets that may play a critical role in the surface expression of alpha-granule TSP during platelet activation.     

Immuno-electron microscopical demonstration of lysosomes in human blood platelets and megakaryocytes using anti-cathepsin D

Immunocytochemistry with affinity-purified anti-human cathepsin D was applied to ultrathin frozen sections of human bone marrow megakaryocytes and of blood platelets from peripheral blood. The fixative used was paraformaldehyde (concentration gradient 2----8%). Protein A/colloidal gold (5 and 8) particles were used as second label. Cathepsin D was localized in primary and secondary lysosomes in blood platelets and in primary and secondary lysosomes in megakaryocytes. Primary lysosomes in megakaryocytes were identified by their localization on the trans-side of the Golgi complex and secondary lysosomes by the presence of inclusions. The lysosomes in platelets differed from alpha-granules by being smaller, lacking an electron dense core, and by the presence of a transparent submembrane halo. Platelets undergoing a release reaction after stimulation with thrombin showed cathepsin-D staining in the surface-connecting tubules.     

Expression of stanniocalcin-1 in megakaryocytes and platelets

Stanniocalcin-1 (STC) is a 56-kDa homodimeric glycoprotein hormone originally found in fish, in which it regulates calcium/phosphate homeostasis and protects against toxic hypercalcaemia. The recently characterized human STC is 80% similar to fish STC. We have earlier reported a high expression of STC in terminally differentiated human and rodent brain neurones, and found that STC contributes to the maintenance of their integrity. Here, we report that mature megakaryocytes and platelets display high STC content. K562 cells, induced to megakaryocytoid differentiation in vitro, acquired expression of STC, which was not seen in untreated K562 cells or cells induced to erythroid differentiation.     

The 5-hydroxytryptamine system of blood platelets: physiology and pathophysiology

The 5-hydroxytryptamine (5HT)-system of human blood platelets consists of a relatively specific uptake mechanism for 5HT at the plasma membrane, intracellular storage organelles (dense bodies), a metabolizing enzyme (monoaminoxidase B) and a 5HT2-receptor whose stimulation leads to activation of the phosphatidylinositide turnover, a rise in free cytoplasmic Ca2+, phosphorylation of proteins and a shape change reaction. There is neither a relevant 5HT-biosynthesis nor a marked physiological 5HT-turnover in platelets. Under physiological conditions the platelet 5HT-system may have a role as a scavenger for free extracellular 5HT and in hemostasis. Disturbances which have been described in pathophysiological states include impairment of 5HT-uptake (hypertension, migraine), impairment of 5HT-storage (storage pool deficiencies, thromboembolic disorders, hypertension) and increased sensitivity to activating agents like 5HT (cardiovascular disorders, diabetes). Besides their role in physiology and pathophysiology platelets may be useful partial models for vascular smooth muscle cells.     

Super-resolution imaging and quantification of megakaryocytes and platelets

Abstract

Recent advances in super-resolution (sub-diffraction limited) microscopy have yielded remarkable insights into the nanoscale architecture and behavior of cells. In addition to the capacity to provide sub 100 nm resolution, these technologies offer unique quantitative opportunities with particular relevance to platelet and megakaryocyte biology. In this review, we provide a short introduction to modern super-resolution microscopy, its applications in the field of platelet and megakaryocyte biology, and emerging quantitative approaches which will allow for unprecedented insights into the biology of these unique cell types.     

Identification of primary lysosomes in human megakaryocytes and platelets

The presence of lysosomal enzymes in human platelets is well documented; the identity of the "lysosome," however, has been the subject of some disagreement. In order to determine the time of appearance and subcellular localization of two lysosomal enzymes in megakaryocytes (MK) and platelets, we examined normal human bone marrow and blood by electron microscopy and cytochemistry. Acid phosphatase (AcPase) was present in the Golgi region in the youngest recognizable MK, as well as in those with a considerable degree of cytoplasmic maturation. Heavy reaction product was usually confined to one or two Golgi-associated cisternae and coated vesicles; other Golgi cisternae were sometimes lightly reactive. In mature MK, reaction product was limited to vesicles of variable size, but smaller than alpha-granules. Another lysosomal enzyme, arylsulfatase (AS), was localized in similar small vesicles in MK of all stages; it could not be demonstrated in the Golgi complex. Vesicles containing AS were also found in about 25% of platelet profiles, whereas vesicles containing AcPase were found in only about 15% of platelet profiles. The alpha-granules of all MK and platelets examined were negative for both enzymes. We conclude that the enzyme-containing vesicles in these cells constitute the lysosomes and that they are distinct from other platelet organelles. Since there was no evidence that they had participated in any digestive event, we believe that they are primary lysosomes, whose contents are secreted during platelet aggregation and the release reaction.     

Methods for genetic modification of megakaryocytes and platelets

During recent decades there have been major advances in the fields of thrombosis and haemostasis, in part through development of powerful molecular and genetic technologies. Nevertheless, genetic modification of megakaryocytes and generation of mutant platelets in vitro remains a highly specialized area of research. Developments are hampered by the low frequency of megakaryocytes and their progenitors, a poor efficiency of transfection and a lack of understanding with regard to the mechanism by which megakaryocytes release platelets. Current methods used in the generation of genetically modified megakaryocytes and platelets include mutant mouse models, cell line studies and use of viruses to transform primary megakaryocytes or haematopoietic precursor cells. This review summarizes the advantages, limitations and technical challenges of such methods, with a particular focus on recent successes and advances in this rapidly progressing field including the potential for use in gene therapy for treatment of patients with platelet disorders.     

Nonimmune interaction of leukocytes with platelets and megakaryocytes

Platelet-leukocyte interaction was observed in an asymptomatic woman. After incubation in the patient's EDTA-plasma, autologous and allogeneic platelets adhered to the surfaces of neutrophils, monocytes, macrophages and, rarely, eosinophils. Monocytes, macrophages, and occasionally neutrophils phagocytosed platelets. Degranulation of peroxidase-positive lysosomes into the platelet-containing phagosome was demonstrated ultrastructurally. Bone marrow studies indicated that bands and earlier neutrophilic precursors did not participate in the reaction, and that neutrophils adhered to, and were rarely engulfed by megakaryocytes. Sequential exposure of the patient's EDTA-plasma to platelets and leukocytes indicated that a nondialyzable factor(s) was first absorbed by platelets which then interacted with leukocytes. The reaction proceeded best in the presence of EDTA at 21 degrees C, and was inhibited or dissociated by divalent cations or at 37 degrees C. Metabolic integrity of both platelets and leukocytes was also essential for the reaction since each was inhibited by formalin fixation and partially inhibited by the metabolic inhibitor 2-deoxyglucose. Formalin-treated platelets continued to absorb the plasma factor(s). The plasma and the cell fractions were inactivated by periodate and nonspecific protease. Treatment of the platelets with trypsin or the leukocytes with neuraminidase diminished the interaction by 50%. The reaction was also interfered with by concanavalin A. Immunofluorescent and immunoabsorption studies failed to identify an immune component of this interaction. These findings indicate that the plasma factor(s) and the cell surface receptors are nonimmune glycoconjugates and consequently differ from previously documented cases of platelet-leukocyte interaction.     

Methods for genetic modification of megakaryocytes and platelets

During recent decades there have been major advances in the fields of thrombosis and haemostasis, in part through development of powerful molecular and genetic technologies. Nevertheless, genetic modification of megakaryocytes and generation of mutant platelets in vitro remains a highly specialized area of research. Developments are hampered by the low frequency of megakaryocytes and their progenitors, a poor efficiency of transfection and a lack of understanding with regard to the mechanism by which megakaryocytes release platelets. Current methods used in the generation of genetically modified megakaryocytes and platelets include mutant mouse models, cell line studies and use of viruses to transform primary megakaryocytes or haematopoietic precursor cells. This review summarizes the advantages, limitations and technical challenges of such methods, with a particular focus on recent successes and advances in this rapidly progressing field including the potential for use in gene therapy for treatment of patients with platelet disorders.     

Conditional overexpression of transgenes in megakaryocytes and platelets in vivo

Megakaryocyte (MK)-specific transgene expression has proved valuable in studying thrombotic and hemostatic processes. Constitutive expression of genes, however, could result in altered phenotypes due to compensatory mechanisms or lethality. To circumvent these limitations, we used the tetracycline/doxycycline (Tet)-off system to conditionally over-express genes in megakaryocytes and platelets in vivo. We generated 3 transactivator transgenic lines expressing the Tet transactivator element (tTA), under the control of the MK-specific platelet factor 4 promoter (PF4-tTA-VP16). Responder lines were simultaneously generated, each with a bidirectional minimal cytomegalovirus (CMV)-tTA responsive promoter driving prokaryotic beta-galactosidase gene, as a cellular reporter, and a gene of interest (in this case, the mitotic regulator Aurora-B). A transactivator founder line that strongly expressed PF4-driven tTA-viral protein 16 (VP16) was crossbred to a responder line. The homozygous double-transgenic mouse line exhibited doxycycline-dependent transgene overexpression in MKs and platelets. Using this line, platelets were conveniently indicated at sites of induced stress by beta-galactosidase staining. In addition, we confirmed our earlier report on effects of constitutive expression of Aurora-B, indicating a tight regulation at protein level and a modest effect on MK ploidy. Hence, we generated a new line, PF4-tTA-VP16, that is available for conditionally overexpressing genes of interest in the MK/platelet lineage in vivo.     

Expression of adhesion antigens of human bone marrow megakaryocytes, circulating megakaryocytes and blood platelets.

There is evidence that mature megakaryocytes migrate into sinusoids, enter the blood and fragment in the vascular bed. We wondered whether differences in expression of adhesion antigens could be associated with the egress of megakaryocytes from bone marrow into the peripheral blood or the fragmentation into platelets. Megakaryocytes from human marrow were purified by counterflow centrifugal elutriation followed by a glycoprotein Ib-dependent agglutination procedure. Megakaryocytes from central venous blood and pulmonary arteries were purified by counterflow centrifugal elutriation alone. Adhesion antigens were labelled in an immunohistochemical assay. Both bone marrow megakaryocytes and platelets from healthy volunteers stained > 75% positive for CD36, CD41, CD42, Cdw49b (alpha subunit VLA2), Cdw49e (alpha subunit VLA5), Cdw49f (alpha subunit VLA6) and CD62. Circulating megakaryocytes, although > 75% positive for CD41, had, unlike platelets and bone marrow megakaryocytes, a reduced and remarkable heterogeneous (5-100% positive) labelling with antibodies against Cdw49b, Cdw49e, Cdw49f. These results could be confirmed by comparing the bone marrow megakaryocytes, circulating megakaryocytes and platelets from 7 patients that were recovered and processed at the same time. Morphologically mature, circulating megakaryocytes have, unlike bone marrow megakaryocytes, a heterogeneous expression of adhesion antigens, especially of Cdw49b, Cdw49e, and Cdw49f.     

Sustained thrombocytopenia in mice: serial studies of megakaryocytes and platelets

We studied thrombopoiesis in mice after the experimental induction of sustained, immune thrombocytopenia with platelet antiserum (PAS). Utilizing light and electron microscopy and a digital image analyzer to determine platelet sectional areas, we examined platelets and megakaryocytes (MK) after 120 h of sustained, severe thrombocytopenia (120CT) and during recovery from thrombocytopenia at 48 h (48R), 72 h (72R), and 120 h (120R) after cessation of administration of PAS. Mean platelet volume (MPV), determined by electrical impedance, also was measured at each time point. Platelets at 120CT (platelet count less than 50,000/microliter), 48R (platelet count 100-200,000/microliter), and 72R (platelet count approximately 1 x 10(6)/microliter) were significantly larger in sectional area than control platelets and contained increased profiles of endoplasmic reticulum and Golgi cisternae, a lower concentration of surface-connected canalicular system, and occasional membrane complexes. The largest median platelet sectional area was detected at 48R and was the largest median value observed in response to either chronic or acute thrombocytopenia. At 120R, most platelets were normal in size and cytoplasmic appearance, although some large cells remained present in the circulation. MPV paralleled the morphometric changes in platelet sectional area. MK were increased in number at 120CT, 48R, 72R, and 120R. In addition, at least half of the MK examined at 48R contained small areas of cytoplasm, devoid of organelles, that were interspersed between larger areas of organelle-filled, undemarcated cytoplasm. The modal bone marrow megakaryocyte ploidy class, determined using two-color fluorescence-activated flow cytometry, shifted from 16N to 32N in response to sustained thrombocytopenia. In contrast, during recovery and development of rebound thrombocytosis, the relative frequency of 8N megakaryocytes was significantly increased. Because there was no consistent correlation between megakaryocyte cytoplasmic characteristics and platelet morphology, these data support the hypothesis that platelet formation is not determined by compartmentalization of MK cytoplasm into platelet areas as MK mature in the bone marrow, but involves a rearrangement of MK cytoplasm immediately prior to platelet release.     

Alpha-granule pool of glycoprotein IIb-IIIa in normal and pathologic platelets and megakaryocytes

Using an immunogold staining technique and electron microscopy, we investigated the localization of the alpha-granule pool of glycoprotein (GP) IIb-IIIa in normal platelets and maturing megakaryocytes (MK), in pathologic platelets from a patient with type I Glanzmann's thrombasthenia (GT), and from three patients with the gray platelet syndrome (GPS). In normal resting platelets, GPIIb-IIIa was observed on the plasmatic side of the plasma membrane, the open canicular system (OCS) membranes, and along the internal face of the alpha-granule membrane. This location was found with three monospecific polyclonal antibodies: one anti-GPIIb-IIIa antibody, the second specific for GPIIb, and the third specific for GPIIIa. After thrombin stimulation, the alpha-granule labeling disappeared whereas membrane labeling increased. Platelets from GT did not display labeling on plasma membranes, OCS membranes, or alpha-granule membranes. Platelets from the three patients with GPS displayed intense labeling of the plasma membrane and the OCS membrane, as well as the abnormal small alpha-granules and along the inside of large vacuoles (which contain the granule membrane protein [GMP]-140). In cultured immature MK from normal progenitors, both peptide components of GPIIb-IIIa appeared in the Golgi saccules and vesicles, and in the small precursors of alpha-granules, labeling both their membranes and their matrix. It was then observed only on the membrane of the mature MK alpha-granules, although labeling was less consistent than on the platelet granules. The MK plasma membrane and demarcation membrane system also displayed GPIIb-IIIa labeling. In conclusion, this study demonstrates that GPIIb-IIIa is present on the internal face of the alpha-granule membranes of platelets (where it appears early during MK maturation) as well as in the abnormal alpha-granules of gray platelets; it is absent from GT type I platelets.