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Other molecular signals for megakaryocyte differentiation include GM-CSF, IL-3, IL-6, IL-11, chemokines (SDF-1, FGF-4), [3] and erythropoietin. [4] The cell eventually reaches megakaryocyte stage and loses its ability to divide. However, it is still able to replicate its DNA and continue development, becoming polyploid. [4]
In order to eventually produce a megakaryocyte, the haematopoietic stem cell must generate myeloid cells, so it becomes a common myeloid progenitor, CFU-GEMM. This in turn develops into CFU-Meg, which is the colony forming unit that leads to the production of megakaryocytes. [1] [2] [3] Some sources prefer the term "CFU-Mega". [4]
It has been discovered that these cells have a high replating efficiency, meaning that when taken from the umbilical cord and grown in culture, a high percentage of these cells are able to produce colonies. The results of studies conducted by Carow, Hangoc, and Broxmeyer in 1993 reveal that the CFU-GEMM can be classified as a stem cell due to ...
Promegakaryocyte. A promegakaryocyte is a precursor cell for a megakaryocyte, the development of which proceeds as follows: [1]. CFU-Meg (hematopoietic stem cell/hemocytoblast) → megakaryoblast → promegakaryocyte → megakaryocyte
Megakaryocyte–erythroid progenitor cells must commit to becoming either platelet-producing megakaryocytes via megakaryopoiesis or erythrocyte-producing erythroblasts via erythropoiesis. [ 2 ] [ 3 ] Most of the blood cells produced in the bone marrow during hematopoiesis come from megakaryocyte–erythroid progenitor cells.
During thrombopoiesis, the promegakaryocyte matures into the form of a megakaryocyte. From the megakaryocyte, platelets are formed. [1] The megakaryoblast is the beginning of the thrombocytic series or platelet forming series. Megakaryoblasts typically have a large oval-shaped nucleus or a nucleus that is lobed with many nuclei. [2]
CFU-E is a stage of erythroid development between the BFU-E stage and the pro-erythroblast stage. CFU-E colony assay is designed to detect how many colony-forming-units of erythroid lineage there are in a hematopoietic tissue (bone marrow, spleen, or fetal liver), which may be reflective of the organism’s demand for oxygen delivery to the tissues or a hematopoietic disorder.
megakaryocyte: platelet formation [9] rodent: hepatocyte: regeneration [10] rodent: trophoblast giant cell: placental development, nourishment of embryo [11] plant: Arabidopsis Thaliana: trichome: defense from herbivory, homeostasis [12] plant: leaf epidermal cell: leaf size, structure [13] plant: endosperm: nourishment of embryo [14] nematode ...