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Docking and fusion sites in human endothelial cells imaged and measured by using atomic force microscopy (2004)

Schneider, S. W. ; Ossig, R. ; Görge, T. ; [et al.]

Oxford, UK; Malden, USA : Blackwell Publishing Ltd/Inc

Experimental dermatology 13 (2004), S. 0

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ISSN: 1600-0625

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Medicine

Notes: The vascular endothelium with its salient location at the interface between blood and tissue plays a pivotal role in the process of blood coagulation and inflammation. The transition into a procoagulatory and proinflammatory state upon stimulation (i.e. neuropeptides) is referred to as endothelial cell activation. One fundamental characteristic of this activation is the induction of von Willebrand factor (vWF), IL-8, and P-selectin exocytosis. These molecules are stored in large (up to 3 µm) cone-like vesicles called Weibel Palade bodies (WPBs). By using atomic force microscopy (AFM), we are able to visualize the apical surface topography of human endothelial cells with nanometer resolution. In addition, AFM allows to measure local cell stiffness with a spatial resolution of 100 nm. In previous studies, we showed that endothelial cells have a readily releasable pool of WPBs. In resting cells, this intracellular docked vesicle pool can be imaged as plasma membrane protrusions with a height of 140 ± 50 nm (±SEM; n = 8) and a diameter of 275 ± 85 nm (±SEM; n = 8). Stiffness measurements revealed that humps are characterized by decreased cell membrane stiffness of 30% compared to surrounding cell membrane due to a reduced subapical actin network. After stimulation of the cells with hyperosmolaric solutions or histamine, these docked WPBs immediately fuse with the plasma membrane forming large (diameter: approximately 500 nm) exocytotic pores and release vWF into the supernatant (measured by ELISA) and expose P-selectin. Immunostaining of vWF was found to be localized next to the exocytotic pores imaged by AFM. The data indicate that human endothelial cells have a readily releasable pool of WPBs that allows the instantaneous release of vWF, IL-8, and exposure of P-selectin. These distinct areas of exocytosis are characterized by cell membrane protrusions and decreased cell membrane stiffness due to a reduced actin cortical network.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.0906-6705.2004.0212az.x

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Volume dynamics in migrating epithelial cells measured with atomic force microscopy (2000)

Schneider, S. W. ; Pagel, P. ; Rotsch, C. ; [et al.]

Springer

Pflügers Archiv 439 (2000), S. 297-303

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ISSN: 1432-2013

Keywords: Atomic force microscope Elasticity IK channel Polarization Migration

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract. Migration of transformed renal epithelial cells (transformed Madin-Darby canine kidney cells, MDCK-F cells) relies on the activity of a Ca2+-sensitive K+ channel (IK channel) that is more active at the rear end of these cells. We have postulated that intermittent IK channel activity induces local cell shrinkage at the rear end of migrating MDCK-F cells and thereby supports the cytoskeletal mechanisms of migration. However, due to the complex morphology of MDCK-F cells we have not yet been able to measure volume changes directly. The aim of the present study was to devise a new technique employing atomic force microscopy (AFM) to measure the volume of MDCK-F cells in their physiological environment and to demonstrate its dependence on IK channel activity. The spatial (x, y and z) co-ordinates of each pixel of the three-dimensional image of MDCK-F cells allow calculation of the volume of the column "underneath" a given pixel. Thus, total cell volume is the sum of all pixel-defined columns. The mean volume of 17 MDCK-F cells was 2500±300 fl. Blockade of the IK channel with the specific inhibitor charybdotoxin (CTX) increased cell volume by 17±4%; activation of IK by elevating the intracellular [Ca2+] with the Ca2+ ionophore ionomycin decreased cell volume by 19±3%. Subtraction images (experimental minus control) reveal that swelling and shrinkage occur predominantly at the rear end of MDCK-F cells. In summary, our experiments show that AFM allows the measurement not only of total cell volume of living cells in their physiological environment but also the tracing of local effects induced by the polarized distribution of K+ channel activity.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004249900176

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Imaging excised apical plasma membrane patches of MDCK cells in physiological conditions with atomic force microscopy (1997)

Lärmer, J. ; Schneider, S. W. ; Danker, T. ; [et al.]

Springer

Pflügers Archiv 434 (1997), S. 254-260

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ISSN: 1432-2013

Keywords: Key words Atomic force microscopy ; Patch clamp ; MDCK cells ; Plasma membrane ; Membrane protein

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract We combined the patch-clamp technique with atomic force microscopy (AFM) to visualize plasma membrane proteins protruding from the extracellular surface of cultured kidney cells (MDCK cells). To achieve molecular resolution, patches were mechanically isolated from whole MDCK cells by applying the patch-clamp technique. The excised inside-out patches were transferred on freshly cleaved mica and imaged with the AFM in air and under physiological conditions (i.e. in fluid). Thus, the resolution could be increased considerably (lateral and vertical resolutions 5 and 0.1 nm, respectively) as compared to experiments on intact cells, where plasma membrane proteins were hardly detectable. The apical plasma membrane surface of the MDCK cells showed multiple protrusions which could be identified as membrane proteins through the use of pronase. These proteins had a density of about 90 per μm², with heights between 1 and 9 nm, and lateral dimensions of 20–60 nm. Their frequency distribution showed a peak value of 3 nm for the protein height. A simplified assumption – modelling plasma membrane proteins as spherical structures protruding from the lipid bilayer – allowed an estimation of the possible molecular weights of these proteins. They range from 50 kDa to 710 kDa with a peak value of 125 kDa. We conclude that AFM can be used to study the molecular structures of membranes which were isolated with the patch-clamp technique. Individual membrane proteins and protein clusters, and their arrangement and distribution in a native plasma membrane can be visualized under physiological conditions, which is a first step for their identification.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004240050393

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Molecular weights of individual proteins correlate with molecular volumes measured by atomic force microscopy (1998)

Schneider, S. W. ; Lärmer, J. ; Henderson, R. M. ; [et al.]

Springer

Pflügers Archiv 435 (1998), S. 362-367

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ISSN: 1432-2013

Keywords: Key words Atomic force microscopy ; Protein molecule imaging ; Molecular volume

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Proteins are usually identified by their molecular weights, and atomic force microscopy (AFM) produces images of single molecules in three dimensions. We have used AFM to measure the molecular volumes of a number of proteins and to determine any correlation with their known molecular weights. We used native proteins (the TATA-binding protein Tbp, a fusion protein of glutathione-S-transferase and the renal potassium channel protein ROMK1, the immunoglobulins IgG and IgM, and the vasodilator-stimulated phosphoprotein VASP) and also denatured proteins (the red blood cell proteins actin, Band 3 and spectrin separated by SDS-gel electrophoresis and isolated from nitrocellulose). Proteins studied had molecular weights between 38 and 900 kDa and were imaged attached to a mica substrate. We found that molecular weight increased with an increasing molecular volume (correlation coefficient = 0.994). Thus, the molecular volumes measured with AFM compare well with the calculated volumes of the individual proteins. The degree of resolution achieved (lateral 5 nm, vertical 0.2 nm) depended upon the firm attachment of the proteins to the mica. This was aided by coating the mica with suitable detergent and by imaging using the AFM tapping mode which minimizes any lateral force applied to the protein. We conclude that single (native and denatured) proteins can be imaged by AFM in three dimensions and identified by their specific molecular volumes. This new approach permits detection of the number of monomers of a homomultimeric protein and study of single proteins under physiological conditions at the molecular level.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004240050524

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