GPIIb and GPIIIa amino acid sequences deduced from human megakaryocyte cDNAs

Platelet GPIIbIIIa is only synthesized in megakaryocyte or in cell lines with megakaryocytic features. The sequence for GPIIb and GPIIIa have recently been derived from cDNAs obtained from HEL cells. The sequence of these proteins produced by the megakaryocyte, has however, not been determined yet. This study describes full length cDNAs for GPIIb and GPIIIa isolated from megakaryocyte cDNA libraries. The cDNA sequences indicate the presence of nucleotide differences, between the sequence of the GPIIIa cDNAs from HEL cells, endothelial cells and megakaryocytes. One difference was also observed between HEL and megakaryocyte GPIIb at position 633 where a cystein in the megakaryocyte GPIIb, is replaced by a serine in the HEL sequence. The mRNA species for GPIIb (3.4kb) and GPIIIa (6.1 kb) were of the same size in HEL cells and human megakaryocytes.     

重组红细胞生成素对小鼠巨核细胞后期成熟及血小板生成的影响

本文应用血小板生成液体培养体系,检测了重组人红细胞生成素(r-EPO)对巨核细胞成熟及血小板生成的影响。r-EPO 能在1U 至6~U/ml 浓度范围内增加体系血小板数,r-EPO剂量与血小板数之间呈线性关系。r-EPO 还能促进巨核细胞 DNA 合成,并使 Ⅱ、Ⅳ 期巨核细胞比例增加,Ⅰ、Ⅱ 期巨核细胞比例减少。结果表明:r-EPO 可以促进巨核细胞成熟,并作为一种主要刺激因子,以增加血小板数的方式促进血小板生成。     

Cytokine production by a megakaryocytic cell line

Summary The regulation of megakaryopoeisis by cytokines is not yet well understood. It is possible that autocrine loops are established during megakaryocyte growth and differentiation, aiding in the maturation of these cells. The CHRF-288-11 human megakaryoblastic cell line has been examined for cytokine production in growing cells and cells stimulated to differentiate by the addition of phorbol esters. It has been demonstrated that these cells produce RNA corresponding to the interleukins IL-1α, 1β, 3, 7, 8, and 11, granulocyte-macrophage colony stimulating factor (GM-CSF), stem cell factor (SCF), transforming growth factor-β (TGF-β), tumor necrosis factor-α (TNF-α), interferon-α (INF-α), and basic fibroblast growth factor (bFGF). Additionaly, RNA corresponding to the receptors for IL-6, GM-CSF, SCF, INF-α,β, bFGF, and monocyte colony stimulating factor (M-CSF) were also expressed by the cells. The receptor for TNF-α was detected immunologically. Analysis at the protein level demonstrated that significant amounts of INF-α, TNF-α, GM-CSF, SCF, IL-1α, and a soluble form of the IL-6 receptor were produced by the cells. Addition of phorbol esters to CHRF-288-11 cells enhances their megakaryocytic phenotype; such treatment also results in increased secretion of INF-α, TNF-α, and GM-CSF. These results suggest that potential autocrine loops are established during the differentiation of CHRF-288-11 cells, which may alter the capability of the cell to differentiate. These findings are similar to those recently obtained for marrow-derived megakaryocytes (Jiang et al.) suggesting that CHRF-288-11 cells provide a useful model system for the study of cytokine release during megakaryocyte differentiation.     

Differential localization of P-selectin and von Willebrand factor during megakaryocyte maturation

Abstract

An important step in megakaryocyte maturation is the appropriate assembly of at least two distinct subsets of α-granules. The mechanism that sorts the α-granule components into distinct structures and mediates their release in response to specific stimuli is now emerging. P-selectin and von Willebrand factor are two proteins present in the α-granules that recognize P-selectin glycoprotein ligand on neutrophils and collagen in the subendothelial matrix. These proteins may play an important role in determining the differential release of the α-granule contents in response to external stimuli. If P-selectin and von Willebrand factor are localized in the same or different α-granules is not known. To clarify this question, we analyzed by immunoelectron microscopy the localization of von Willebrand factor and P-selectin during the maturation of wild-type and Gata1^low megakaryocytes induced in vivo by treating animals with thrombopoietin. Gata1^low is a hypomorphic mutation that blocks megakaryocyte maturation, reduces the levels of von Willebrand factor expression and displaces P-selectin on the demarcation membrane system. The maturation block induced by this mutation is partially rescued by treatment in vivo with thrombopoietin. In immature megakaryocytes, both wild-type and Gata1^low, the two receptors were co-localized in the same cytoplasmic structures. By contrast, the two proteins were segregated to separate α-granule subsets as the megakaryocytes matured. These observations support the hypothesis that P-selectin and von Willebrand factor may ensure differential release of the α-granule content in response to external stimuli.     

Lineage-Biased Hematopoietic Stem Cells Are Regulated by Distinct Niches

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Role of a serine/threonine kinase,Mst1, in megakaryocyte differentiation

Platelets, which play a central role in thrombosis and hemostasis, develop from megakaryocytes. Signal transduction originated from the megakaryocyte growth and development factor, the Mpl ligand, which leads to megakaryocyte differentiation, polyploidization, and maturation, has been gradually characterized. In this study, we report the inducibility of Mst1, a recently described serine/threonine kinase, by Mpl ligand and the effect of its induced expression on megakaryocyte differentiation. The steady‐state level of mst1 message and Mst1‐associated kinase activity increased in response to Mpl ligand. Ectopic expression of human mst1 in a mouse megakaryocytic cell line resulted in a drastic increase in DNA content per cell. Elevated expression of megakaryocyte differentiation markers, such as acetylcholine esterase, PF4, and GPIIb was also observed in hmst1‐expressing cells. Activation of p38 MAPK, a known downstream effector of Mst1, was shown to be required for polyploidization, but not for enhanced expression of differentiation markers. Our study thus designates Mst1 as a Mpl ligand‐responsive signaling molecule that promotes induction of lineage‐specific cellular programming. J. Cell. Biochem. 76:44–60, 1999. © 1999 Wiley‐Liss, Inc.     

Large‐scale culture of a megakaryocytic progenitor cell line with a single‐use bioreactor system

The increasing application of regenerative medicine has generated a growing demand for stem cells and their derivatives. Single‐use bioreactors offer an attractive platform for stem cell expansion owing to their scalability for large‐scale production and feasibility of meeting clinical‐grade standards. The current work evaluated the capacity of a single‐use bioreactor system (1 L working volume) for expanding Meg01 cells, a megakaryocytic (MK) progenitor cell line. Oxygen supply was provided by surface aeration to minimize foaming and orbital shaking was used to promote oxygen transfer. Oxygen transfer rates (k_La) of shaking speeds 50, 100, and 125 rpm were estimated to be 0.39, 1.12, and 10.45 h^?1, respectively. Shaking speed was a critical factor for optimizing cell growth. At 50 rpm, Meg01 cells exhibited restricted growth due to insufficient mixing. A negative effect occurred when the shaking speed was increased to 125 rpm, likely caused by high hydrodynamic shear stress. The bioreactor culture achieved the highest growth profile when shaken at 100 rpm, achieving a total expansion rate up to 5.7‐fold with a total cell number of 1.2 ± 0.2 × 10⁹ cells L^?1. In addition, cells expanded using the bioreactor system could maintain their potency to differentiate following the MK lineage, as analyzed from specific surface protein and morphological similarity with the cells grown in the conventional culturing system. Our study reports the impact of operational variables such as shaking speed for growth profile and MK differentiation potential of a progenitor cell line in a single‐use bioreactor. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 34:362–369, 2018