Figure 4 Morphological and cytochemical changes in HPB-AML-I cell

Figure 4 Morphological and cytochemical changes in HPB-AML-I cells following

the induction of differentiation toward mesenchymal lineage cells. Undifferentiated HPB-AML-I cells observed with an inverted microscope are shown for comparison (A). A representative HPB-AML-I cell induced to differentiate toward adipocyte and showing spindle-like morphology and cytoplasmic vacuoles is indicated with an arrow (B). Undifferentiated (C, E) and differentiated (D, F) HPB-AML-I cells were stained with Sudan Black B (C, D) and oil red O (E, F). The nucleus was counterstained with hematoxylin. Positive Sudan Black B and oil red O staining of cytoplasmic vacuoles of the differentiated HPB-AML-I cells is indicated with an arrow. Following the induction of differentiation toward chondrocytes, HPB-AML-I cells showed polygonal morphology with a number of cytoplasmic vacuoles (arrow) (G). AUY-922 molecular weight The micromass of undifferentiated (H) and differentiated (I) HPB-AML-I cells were stained with toluidine learn more blue. The presence of lacunae (arrows) and the toluidine blue-positive extracellular matrix (arrowheads) characteristic for a cartilage were observed following the induction of chondrogenesis. The osteogenic-differentiated HPB-AML-I cells demonstrated a number of cell processes (arrow) and an eccentrically located nucleus (arrowhead) (J).

Undifferentiated (K) and differentiated (L) HPB-AML-I cells were cytochemically examined for alkaline phosphatase expression. The nucleus was counterstained with Safranin O. Positive reactions are shown in the differentiated HPB-AML-I cells with an arrow. Undifferentiated (M) and differentiated (N) HPB-AML-I cells were stained with von Kossa method. The nucleus was counterstained with BTK inhibitor solubility dmso nuclear fast red. The extracellular depositions of calcium following the induction of osteogenesis are indicated

with an arrow. Original magnification x400; Size bar: 20 μm. Two weeks after the induction of chondrogenesis, the differentiated HPB-AML-I cells showed polygonal morphology, which made them distinct from the undifferentiated cells. Inverted microscopic examination demonstrated 6-phosphogluconolactonase the presence of a number of vacuoles in the cytoplasm of differentiated HPB-AML-I cells (Figure 4G). In contrast to the undifferentiated cells (Figure 4H), the differentiated HPB-AML-I cells formed lacunae. The proteoglycan-rich extracellular matrix, as indicated by positive toluidine blue staining, surrounded the lacunae (Figure 4I). The presence of lacunae, as well as extracellular proteoglycan accumulation, suggested that the micromass of chondrogenic-differentiated HPB-AML-I cells acquires the properties of a cartilage. Inverted microscopic examination three weeks after the induction of osteogenesis demonstrated the presence of a number of cell processes and an eccentrically located nucleus in the differentiated HPB-AML-I cells (Figure 4J).

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