Cell Structure and Function Volume 25, Issue 6

Adhesion between Cells and Extracellular Matrix with Special Reference to Hepatic Stellate Cell Adhesion to Three-dimensional Collagen Fibers

Hepatic stellate cells are located in the perisinusoidal space (space of Disse), and extend their dendritic, thin membranous processes and fine fibrillar processes into this space. The stellate cells coexist with a three-dimensional extracellular matrix (ECM) in the perisinusoidal space. In turn the three-dimensional structure of the ECM regulates the proliferation, morphology, and functions of the stellate cell. In this review, the morphology of sites of adhesion between hepatic stellate cells and extracellular matrix is described. Hepatic stellate cells cultured in polystyrene dishes spread well, whereas the cells cultured on or in type I collagen gel become slender and elongate their long cellular processes which adhere directly to the collagen fibers. Cells in type I collagen gel form a large number of adhesive structures, each adhesive area forming a face but not a point. Adhesion molecules, integrins, for the ECM are localized on the cell surface. Elongation of the cellular processes occurs via integrin-binding to type I collagen fibers. The signal transduction mechanism, including protein and phosphatidylinositol phosphorylation, is critical to induce and sustain the cellular processes. Information on the three-dimensional structures of ECM is transmitted via three-dimensional adhesive structures containing the integrins.

Ultrastructural, Immunocytochemical and Flow Cytometry Study of Mouse Peritoneal Cells Stimulated with Carrageenan

In the present paper we performed a morphological characterization of mouse peritoneal cells stimulated in vivo for 24 h with carrageenan (CAR) and lipopolysaccharide (LPS) by ultrastructural and flow cytometry analysis. In all samples, the flow cytometry studies showed the presence of three major populations consisting of monocytes, macrophages and lymphocytes. A special recruitment of monocytes was detected in CAR-injected mice. Macrophages and monocytes from CAR-treated mice displayed a characteristic phenotype, with a larger number of cytoplasmic vacuoles and numerous membrane projections, as compared to the cells collected from LPS- and PBS-injected mice. The induction of vacuolization was also confirmed upon in vitro treatment with CAR for 15 min to 24 h. The in vivo CAR-induced vacuoles were not related to lipid storage as judged by the lack of lipidic labeling after imidazole treatment at the ultrastructural level. In order to investigate the acidic nature of the vacuoles we used acidothropic probes, Lysotracker Yellow (LY) and Acridine Orange (AO). CAR injection activated the ability of peritoneal cells to incorporate LY around 2-5 times higher than control cells. However, the AO incorporation was 10-fold lower in CAR-stimulated cells than in LPS-stimulated ones. It is possible that the increase in intracellular vacuolization observed in CAR-stimulated cells could be related to exocytosis, since in most vacuoles the inflammatory protein MRP-14 was immunolocalized. The presence of MRP-14 in the culture supernatant of adherent peritoneal cells from CAR-injected mice was further comfirmed by ELISA, suggesting the discharge of MRP-14 enriched vacuole contents in the extracellular medium. We concluded that the morphological characteristics of activated monocytes and macrophages may depend on the nature of the triggering stimuli. Our observations reflect different functional phenotypes of monocytes/macrophages after in vivo stimulation with inflammatory agents such as CAR and LPS.

Scraped-Wounding Causes Activation and Association of C-Src Tyrosine Kinase with Microtubules in Cultured Keratinocytes

In order to elucidate the function of c-Src in keratinocytes, we studied the intracellular distribution of its active and inactive form in cultured normal human keratinocyte, using anti-c-Src monoclonal antibody clone 28, which recognizes the active form of c-Src (dephosphorylated at COOH-terminal residue Tyr 530), and monoclonal antibody clone 327 which recognizes both active and inactive forms. Since c-Src has been suggested to be involved in the control of cell adhesion in other cells, we produced a dynamic condition of cell migration by cutting culture cell colonies into squares to form a mesh pattern with a blade (culture wound model). Before cutting, the active form was expressed in cells located only at the periphery of colonies or isolated migrating cells, and was associated with microtubules. Wounding the colony generated a dramatic and rapid activation of c-Src in a few rows of cells along the cut edges, which were made even at the middle of colony, resulting in the association of the active form with microtubules. This increase of the active form was also detected by immunoblotting of cell extracts. These reactions were inhibited by 1 mM sodium orthovanadate, a protein-tyrosine phosphatase inhibitor. ST 638, a potent Src family tyrosine kinase inhibitor, inhibited the migration of keratinocytes in the culture wound healing model. These results suggest that wounding the culture causes activation of c-Src in keratinocytes, and thus activated c-Src may play a role in the function of microtubules during cell migration, especially at an early stage of wound healing.

Atomic Force Microscopic Evidence for Z-band as a Rigid Disc Fixing the Sarcomere Structure of Skeletal Muscle

Atomic force microscopic images of single skeletal myofibrils showed periodical broad filamentous bands interspaced with narrow rigid bands corresponding to the sarcomere structures of skeletal muscle (Yoshikawa, Y., Yasuike, T., Yagi, A., and Yamada, T. 1999. Biochem. Biophys. Res. Comm., 256: 13-19). In order to identify the narrow rigid bands, comparative studies were made for intact single myofibrils and those treated with calcium-activated neutral protease by use of atomic force microscopy. It was found that (a) the periodical narrow rigid bands present in intact myofibrils were completely absent in myofibrils treated with calcium-activated neutral protease, and that (b) myofibrils treated with calcium-activated neutral protease were very fragile compared with intact myofibrils. As calcium-activated neutral protease selectively removes Z-bands of myofibrils (Reddy, M. K., Etlinger, J. D., Rabinowitz, M., Fischman, D. A., and Zak, R. 1975. J. Biol. Chem., 250: 4278-4284), these results clearly indicate that (a) the narrow rigid bands are the Z-bands, and that (b) the Z-bands are the essential disc supporting the sarcomere structure of skeletal muscle.