Miho Nitou scite author profile

Development of desmin-positive hepatic stellate cells was studied in mice using double immunofluorescent techniques and in vitro cultures with special attention given to their cell lineages. Several studies recently reported on the presence of cells that are immunologically reactive with both antidesmin and anticytokeratin antibodies in young fetal rat livers, and suggested the possibility that these cells give rise to hepatocytes and hepatic stellate cells. At early stages of mouse liver development, stellate cells with desmin-positive filaments were scattered in the liver parenchyma. However, the stellate cells definitely differed from hepatoblasts and hepatocytes in terms of their morphology and expression of desmin and hepatoblast and hepatocyte-specific E-cadherin in the liver. Fetal hepatoblasts and hepatocytes did not react with antidesmin antibodies, nor did desmin-positive stellate cells express E-cadherin in vivo and in vitro. Thus it is likely that desmin-positive stellate cells and hepatoblasts belong to different cell lineages. In the fetal liver, the desmin-positive stellate cells surrounded blood vessels, and extended their processes to haematopoietic cells and megakaryocytes. Many, but not all, hepatoblasts and hepatocytes were observed to be associated with the stellate cells. At fetal stages, cellular processes positive for desmin in the stellate cells were also thick compared with those in the adult liver, in which desmin-positive stellate cells lay in Disse's space and were closely associated with all hepatocytes. These developmental changes in the geography of desmin-positive cells in the liver parenchyma and their morphology may be associated with their maturation and interactions with other cell types.

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Quantitative Analysis of Cell Allocation During Liver Development, Using the spfash-Heterozygous Female Mouse

Shiojiri¹,

Sano²,

Inujima³

et al. 2000

The American Journal of Pathology

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Mosaicism of ornithine transcarbamylase (OTC) expression in hepatocytes was quantitatively analyzed during liver development of the spf(ash)-heterozygous female mouse. Because the mosaic patterns depend on cell migration and cell mixing, such analysis could give insights on the growth pattern or allocation pattern of hepatocytes during liver development. Complex mosaic patterns of OTC-positive and -negative hepatocytes were observed in sections of fetal and postnatal livers. Sizes of patches, which were aggregates of OTC-positive or -negative hepatocytes, increased during development. Patches were slender and comparatively simple in 15.5- and 17.5-day fetal and neonatal livers. Quantitative analysis of patch shapes demonstrated that undulation of patches was maximal at 7 postnatal days. Patches with nodular shapes also started to increase in number at this stage. Isolated patches in sections of fetal livers and postnatal livers three-dimensionally connected with one another. However, especially in fetal livers, in which OTC-positive patches were minor, due to the presence of abundant hemopoietic cells, isolated three-dimensional patches consisting of approximately 5 to 70 cells were often found. They were shaped like slender branching or zigzag-shaped cords, but no definite orientation such as portal-central was observed in them at any stage. These results suggest that hepatocytes contiguously allocate their daughter cells as zigzag-shaped or branching cords at younger stages. Some hepatocytes grow with nodular formation after 7 postnatal days. Migration and mixing of hepatocytes appear to be more extensive at fetal stages than in the adult liver. Immunohistochemical analysis of intercellular junction proteins (E-cadherin, connexins 26 and 32, occludin, and ZO-1) also revealed that their expression and distribution changed in hepatocytes during development, which may be correlated with the OTC mosaic patterns.

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Purification and Culture of Fetal Mouse Hepatoblasts that Are Precursors of Mature Hepatocytes and Biliary Epithelial Cells

Shiojiri

Nitou

2011

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To investigate cell-cell interactions during mammalian liver development, it is essential to separate hepatoblasts (fetal liver progenitor cells) from nonparenchymal cells, including stellate cells, endothelial cells, and hemopoietic cells. Various factors, which may be produced by nonparenchymal cells, could be assayed for their effects on the growth and maturation of separated hepatoblasts. The protocol using immunomagnetic beads coated with anti-mouse E-cadherin antibody is described for efficient isolation of hepatoblasts from cell suspensions of fetal mouse livers. The purity and recovery rate are larger than 95% and approximately 30%, respectively. The protocol may be useful for various studies focusing on the fetal liver progenitor cells.

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Miho Nitou

Purification of Fetal Mouse Hepatoblasts by Magnetic Beads Coated with Monoclonal Anti-E-Cadherin Antibodies and Their In Vitro Culture

Immunohistochemical analysis of development of desmin‐positive hepatic stellate cells in mouse liver

Quantitative Analysis of Cell Allocation During Liver Development, Using the spfash-Heterozygous Female Mouse

Purification and Culture of Fetal Mouse Hepatoblasts that Are Precursors of Mature Hepatocytes and Biliary Epithelial Cells

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