Characterization of Kupffer cells in livers of developing mice

Abstract Background Kupffer cells are well known macrophages of the liver, however, the developmental characteristics of Kupffer cells in mice are not well understood. To clarify this matter, the characteristics of Kupffer macrophages in normal developing mouse liver were studied using light microscopy and immunocytochemistry. Methods Sections of liver tissue from early postnatal mice were prepared using immunocytochemical techniques. The Kupffer cells were identified by their immunoreactivity to the F4/80 antibody, whereas endothelial cells were labelled with the CD-34 antibody. In addition, Kupffer cells and endothelial cells were labelled by systemically injected fluorescently labelled latex microspheres. Tissue slices were examined by fluorescence microscopy. Results Intravenous or intraperitonal injections of microspheres yielded similar patterns of liver cell labelling. The F4/80 positive Kupffer cells were labelled with both large (0.2 μm) and small (0.02 μm) diameter microspheres, while endothelial cells were labelled only with the smaller diameter microspheres. Microsphere labelling of Kupffer cells appeared stable for at least 6 weeks. Cells immunoreactive for F4/80 were identified as early as postnatal day 0, and these cells also displayed uptake of microspheres. Numbers of F4/80 Kupffer cells, relative to numbers of albumin positive hepatocytes, did not show a significant trend over the first 2 postnatal weeks. Conclusions Kupffer cells of the developing mouse liver appear quite similar to those of other mammalian species, confirming that the mouse presents a useful animal model for studies of liver macrophage developmental structure and function

Cellular organization of normal mouse liver: a histological, quantitative immunocytochemical, and fine structural analysis

The cellular organization of normal mouse liver was studied using light and electron microscopy and quantitative immunocytochemical techniques. The general histological organization of the mouse liver is similar to livers of other mammalian species, with a lobular organization based on the distributions of portal areas and central venules. The parenchymal hepatocytes were detected with immunocytochemical techniques to recognize albumin or biotin containing cells. The macrophage Kupffer cells were identified with F4-80 immunocytochemistry, Ito stellate cells were identified with GFAP immunocytochemistry, and endothelial cells were labeled with the CD-34 antibody. Kupffer cells were labeled with intravascularly administered fluorescently labeled latex microspheres of both large (0.5 μm) and small (0.03 μm) diameters, while endothelial cells were labeled only with small diameter microspheres. Neither hepatocytes nor Ito stellate cells were labeled by intravascularly administered latex microspheres. The principal fine structural features of hepatocytes and non-parenchymal cells of mouse liver are similar to those reported for rat. Counts of immunocytochemically labeled cells with stained nuclei indicated that hepatocytes constituted approximately 52% of all labeled cells, Kupffer cells about 18%, Ito cells about 8%, and endothelial cells about 22% of all labeled cells. Approximately, 35% of the hepatocytes contained two nuclei; none of the Kupffer or Ito cells were double nucleated. The presence of canaliculi and a bile duct system appear similar to that reported for other species. The cellular organization of the mouse liver is quite similar to that of other mammalian species, confirming that the mouse presents a useful animal model for studies of liver structure and function

Development, differentiation, and vascular components of subcutaneous and intrahepatic Hepa129 tumors in a mouse model of hepatocellular carcinoma.

Tumor models in mice offer opportunities for understanding tumor formation and development of therapeutic treatments for hepatocellular carcinoma. In this study, subcutaneous or intra-hepatic Hepa129 tumors were established in C3H mice. Tumor growth was determined by daily measurements of subcutaneous tumors and post-mortem studies of subcutaneous and intrahepatic tumors. Administration of Edu was used to determine cell generation dates of tumor cells. Immunohistochemistry with antibodies directed at CD31 or CD34, and intravenous injection of labeled tomato lectin revealed tumor vasculature. Tissue sections also were processed for immunohistochemistry using a panel of antibodies to proteoglycans. Comparison of Edu labeled cells with immunoreactivity allowed determination of development and differentiation of tumor cells after cell generation. Subcutaneous and intrahepatic tumors displayed similar growth over 3 weeks. Immunohistochemistry showed strong labeling for glypican-3, 9BA12, and chondroitin sulfate of tumors in both loci, while normal liver was negative. Tumor regions containing Edu labeled cells did not show significant immunohistochemical labeling for the tumor markers until 2-3 days after Edu treatment; overlap of Edu labeled cells and immunohistochemically labeled tumor regions appeared to reach a maximum at 5 days after Edu treatment. Ectopic subcutaneous tumors displayed vascular ingrowth as the tumor cells expressed immunocytochemical markers; subcutaneous tumors displayed significantly more vascular elements than did intrahepatic tumors

Use of labeled tomato lectin for imaging vasculature structures.

Intravascular injections of fluorescent or biotinylated tomato lectin were tested to study labeling of vascular elements in laboratory mice. Injections of Lycopersicon esculentum agglutinin (tomato lectin) (50-100 µg/100 µl) were made intravascularly, through the tail vein, through a cannula implanted in the jugular vein, or directly into the left ventricle of the heart. Tissues cut for thin 10- to 12-µm cryostat sections, or thick 50- to 100-µm vibratome sections, were examined using fluorescence microscopy. Tissue labeled by biotinylated lectin was examined by bright field microscopy or electron microscopy after tissue processing for biotin. Intravascular injections of tomato lectin led to labeling of vascular structures in a variety of tissues, including brain, kidney, liver, intestine, spleen, skin, skeletal and cardiac muscle, and experimental tumors. Analyses of fluorescence in serum indicated the lectin was cleared from circulating blood within 2 min. Capillary labeling was apparent in tissues collected from animals within 1 min of intravascular injections, remained robust for about 1 h, and then declined markedly until difficult to detect 12 h after injection. Light microscopic images suggest the lectin bound to the endothelial cells that form capillaries and endothelial cells that line some larger vessels. Electron microscopic studies confirmed the labeling of luminal surfaces of endothelial cells. Vascular labeling by tomato lectin is compatible with a variety of other morphological labeling techniques, including histochemistry and immunocytochemistry, and thus appears to be a sensitive and useful method to reveal vascular patterns in relationship to other aspects of parenchymal development, structure, and function

Development, differentiation, and vascular components of subcutaneous and intrahepatic Hepa129 tumors in a mouse model of hepatocellular carcinoma

Tumor models in mice offer opportunities for understanding tumor formation and development of therapeutic treatments for hepatocellular carcinoma. In this study, subcutaneous or intra-hepatic Hepa129 tumors were established in C3H mice. Tumor growth was determined by daily measurements of subcutaneous tumors and post-mortem studies of subcutaneous and intrahepatic tumors. Administration of Edu was used to determine cell generation dates of tumor cells. Immunohistochemistry with antibodies directed at CD31 or CD34, and intravenous injection of labeled tomato lectin revealed tumor vasculature. Tissue sections also were processed for immunohistochemistry using a panel of antibodies to proteoglycans. Comparison of Edu labeled cells with immunoreactivity allowed determination of development and differentiation of tumor cells after cell generation. Subcutaneous and intrahepatic tumors displayed similar growth over 3 weeks. Immunohistochemistry showed strong labeling for glypican-3, 9BA12, and chondroitin sulfate of tumors in both loci, while normal liver was negative. Tumor regions containing Edu labeled cells did not show significant immunohistochemical labeling for the tumor markers until 2-3 days after Edu treatment; overlap of Edu labeled cells and immunohistochemically labeled tumor regions appeared to reach a maximum at 5 days after Edu treatment. Ectopic subcutaneous tumors displayed vascular ingrowth as the tumor cells expressed immunocytochemical markers; subcutaneous tumors displayed significantly more vascular elements than did intrahepatic tumors