Megakaryocyte (MK) progenitors express the CD34 antigen, but the precise stage along the MK differentiation at which the CD34 is turned off is not known. Purified marrow CD34+ cells give rise within 4 days in culture to rare mature MK, suggesting that some MK precursors bear the CD34 antigen. By multiparameter flow cytometry, CD34+ cells bearing platelet glycoproteins (GP) could be detected, but at a low frequency (less than 2% of the marrow CD34+ cells). We used an in vitro liquid suspension culture to selectively amplify MK differentiation. CD34+ cells were isolated after 6 days before a wave of mature MK. These cells gave rise within another 4 days in culture to numerous MK (up to 50%), showing that these CD34+ cells were greatly enriched in MK precursors. This was confirmed by ultrastructural studies that showed the presence of typical promegakaryoblasts. By flow cytometry, three populations of small cell size could be defined: CD34+ GPIIIa-, CD34+ GPIIIa+, and CD34- GPIIIa+ cells. The two GPIIIa+ populations were almost pure immature blastic MK. alpha-Granules were rare in the CD34+ GPIIIa+ cells, whereas they were more developed in the CD34- GPIIIa+ cells, which also exhibited demarcation membranes. Approximately 45% of the two GPIIIa+ cell populations were capable of undergoing at least one cell division and of giving rise to a polyploid progeny. However, proliferation and polyploidization capacities were higher in the CD34+ GPIIIa+ than in the CD34- GPIIIa+ cells. A small fraction of GPIIIa+ cells (about 10%) were able to give rise to MK colonies containing a maximum of 16 cells for the double-positive cells. GPIb was expressed on about sixfold less cells than GPIIIa, but was detected on a few CD34+ cells. Most double-stained (CD34+ GPIb+) cells were polyploid. CD34- GP+ cells (more mature) contained less polyploid MK than the CD34+ GP+ fraction. Altogether, these findings show that CD34 is still expressed on a polyploid transitional immature MK and that GPIIIa is present on some MK progenitors with low proliferative capacities. They also suggest that the expression of CD34 is related to the ability of the MK precursors to accomplish DNA synthesis (either cell division or endomitosis). Such a characterization will facilitate the investigation of the role of the different cytokines on MK differentiation.
We have recently shown that several components from the platelet plasma membrane were also present at different rates in the alpha-granule membrane. This is the case for the glycoprotein (GP) IIb-IIIa (CD41), CD36, CD9, PECAM1, and Rap1b, while the GPIB-IX-V complex was considered to escape the rule. In this investigation, we studied the subcellular localization of GPIb, GPIX, and GPV in the resting platelets of normal subjects, patients with Bernard-Soulier syndrome, patients with Gray platelet syndrome, and human cultured megakaryocytes. Ultra-thin sections of the cells were labeled with antibodies directed against glycocalicin, GPIb, GPIX, and GPV. We have shown that a significant and reproducible labeling for the three GPs was associated with the alpha-granule membrane, accounting for approximately 10% of the total labeling. Furthermore, GPIb labeling appears Willebrand factor (vWF). After thrombin activation, vWF remained close to the limiting membrane of the open canalicular system (OCS), suggesting an early association of both receptor and ligand. Plasma membrane and alpha-granule labeling was virtually absent from the Bernard-Soulier platelets (characterized by a GPIb deficiency), thus proving the specificity of the reaction. In Gray platelets (storage granule deficiency syndrome), the small residual alpha- granules were also occasionally labeled for GPIb, GPIX, and GPIX. Cultured megakaryocytes that displayed the classical GPIb distribution, eg, demarcation and plasma membranes, exhibited also a discrete labeling associated to the alpha-granules. In conclusion, this study shows that, evenly for these three GPs, the alpha-granule membrane mirrors the plasma membrane composition. This might occur through an endocytotic process affecting each plasma membrane protein to a different extent and could have a physiologic relevance in further presentation of a receptor bound to its alpha-granule ligand to the platelet surface.
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.
) is a naturally occurring protein in normal individuals which adopts an abnormal conformation, termed scrapie prion protein (PrP Sc ) that is associated with disease. There is great concern that clinically asymptomatic variant Creutzfeldt-Jacob disease (vCJD) may transmit PrP Sc in blood transfusion products. PrP C is widely expressed and has been found in human blood. The majority of cellular borne PrP C is associated with platelets (84%). Although PrP C mRNA has been demonstrated in platelets, the quantity is unknown and may not reflect the total PrP C present. Objective: To investigate the expression of PrP C in the megakaryocyte lineage. Methods: The expression of PrP C was studied in CD34 + cells, cultured megakaryocytes and platelets using electron microscopy, flow cytometry, semiquantitative RT-PCR and immunofluorescence confocal microscopy. Results and conclusions: The expression of PrP C appeared to increase with differentiation and polyploidization in the megakaryocyte lineage. PrP C was located within platelet a-granules and its source is likely to be from megakaryocyte precursors. If PrP Sc has a similar distribution, these results have implications for the selection of blood donors and preparation of cell-depleted blood products.
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