• Title of article

    Vacuolar structures can be identified by AFM elasticity mapping

  • Author/Authors

    Riethmüller، نويسنده , , Christoph and Schنffer، نويسنده , , Tilman E. and Kienberger، نويسنده , , Ferry and Stracke، نويسنده , , Werner and Oberleithner، نويسنده , , Hans، نويسنده ,

  • Pages
    7
  • From page
    895
  • To page
    901
  • Abstract
    Fluid-filled organelles like vesicles, endosomes and pinosomes are inevitable parts of cellular signalling and transport. Endothelial cells, building a barrier between blood and tissue, can form vacuolar organelles. These structures are implicated in upregulated fluid transport across the endothelium under inflammatory conditions. Vacuolar organelles have been described by transmission electron microscopy so far. Here, we present a method that images and mechanically characterizes intracellular structures in whole cells by atomic force microscopy (AFM). After crosslinking the cellular proteins with the fixative glutaraldehyde, plasma membrane depressions become observable, which are scattered around the cell nucleus. Nanomechanical analysis identifies them as spots of reduced stiffness. Scanning electron microscopy confirms their pit-like appearance. In addition, fluorescence microscopy detects an analogous pattern of protein-poor spots, thereby confirming mechanical rigidity to arise from crosslinked proteins. This AFM application opens up a mechanical dimension for the investigation of intracellular organelles.
  • Keywords
    atomic force microscopy , Endothelial cells , Elasticity mapping , vacuole , vesicle
  • Journal title
    Astroparticle Physics
  • Record number

    2052020