Imaging of the membrane surface of MDCK cells by atomic force microscopy

Lesniewska, Éric; Cachia, Claire; Schreiber, J.; Fornel, Frédérique de; Goudonnet, J. P.

doi:10.1016/s0006-3495(94)80490-4

Cited by 80 publications

(46 citation statements)

References 38 publications

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“…AFM reconstructs an image of a surface from x, y, and z data to develop a three-dimensional topography of any surface at a nanometer level (31). The procedure for AFM imaging of different biological samples such as MDCK cells in the contact and tapping modes has been described elsewhere (16,17,22,30). For surface scanning, C7 cells were seeded on the reverse surface of the filter membrane, and melanoma cells were added to the upper medium (as described in Cells and cell culture), separated from C7 cells by the filter membrane (no physical contact).…”

Section: Methodsmentioning

confidence: 99%

The electrical resistance breakdown assay determines the role of proteinases in tumor cell invasion

Ludwig¹,

Ossig²,

Graessel

et al. 2002

American Journal of Physiology-Renal Physiology

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The electrical resistance breakdown of the Madin-Darby canine kidney (MDCK) cell monolayer provides a continuous assay system for cancer invasion that detects functional changes before morphological alterations. In this study, we address the question of whether physical contact between tumor cell and epithelial monolayer is a prerequisite for tumor cell invasion. When human melanoma cells were seeded directly (i.e., physical contact) on top of an electrically tight epithelial cell layer (5,800 ± 106 Ω · cm2), electrical monolayer leakage led to an 18 ± 3% reduction of transepithelial electrical resistance within 24 h. However, when melanoma cells were seeded close to the basolateral surface of the epithelial cell monolayer but separated by a filter membrane (i.e., no physical contact), electrical leakage occurred even more quickly (42 ± 3% reduction in 24 h). Atomic force microscopy detected discrete structural changes between cells. Electrical leakage was effectively blocked by α2-macroglobulin or ilomastat, inhibitors of matrix metalloproteinases. We conclude that exocytosis of soluble proteases causes electrical breakdown of the MDCK monolayer, independently of physical contact between tumor cells and the monolayer.

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Section: Methodsmentioning

confidence: 99%

The electrical resistance breakdown assay determines the role of proteinases in tumor cell invasion

Ludwig¹,

Ossig²,

Graessel

et al. 2002

American Journal of Physiology-Renal Physiology

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“…Considering the fact that the glycocalyx might hamper detection of fine topographic features on the extracellular face and that the cytoplasmic membrane face is expected to be rather crowded with membrane skeleton elements, 16 Certainly, the fact that membrane skeleton junctions are rather preserved all through the plasma membrane, even after spectrin removal, confirms their functionality as underpinning of the skeleton network. Evaluation of the mechanical properties on both sides of the erythrocyte membrane was assessed from the corresponding elasticity and deformation maps.…”

Section: Structural and Mechanical Heterogeneity Of The Rbc Plasma Mementioning

confidence: 99%

Structural and Mechanical Heterogeneity of the Erythrocyte Membrane Reveals Hallmarks of Membrane Stability

et al. 2013

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The erythrocyte membrane, a metabolically regulated active structure that comprises lipid molecules, junctional complexes, and the spectrin network, enables the cell to undergo large passive deformations when passing through the microvascular system. Here we use atomic force microscopy (AFM) imaging and quantitative mechanical mapping at nanometer resolution to correlate structure and mechanics of key components of the erythrocyte membrane, crucial for cell integrity and function. Our data reveal structural and mechanical heterogeneity modulated by the metabolic state at unprecedented nanometer resolution. ATP-depletion, reducing skeletal junction phosphorylation in RBC cells, leads to membrane stiffening. Analysis of ghosts and shear-force opened erythrocytes show that, in the absence of cytosolic kinases, spectrin phosporylation results in membrane stiffening at the extracellular face and a reduced junction remodeling in response to loading forces. Topography and mechanical mapping of single components at the cytoplasmic face reveal that, surprisingly, spectrin phosphorylation by ATP softens individual filaments. Our findings suggest that, besides the mechanical signature of each component, the RBC membrane mechanics is regulated by the metabolic state and the assembly of its structural elements.

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“…The Auto Tune function of the microscope can help find the proper working frequency [11]. As cells are extremely soft substrates, the best lateral resolution that can be expected is about 10 nm [12][13][14]. Both of these modes have been shown to provide good results in live-cell imaging (Figure 2A), but more relevant results are obtained when combined with light microscopy ( Figure 2B).…”

Section: Instrumentationmentioning

confidence: 99%

Atomic Force Microscopy Imaging of Living Cells

Berquand¹,

Roduit

Kasas

et al. 2010

Micros. Today

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Over the last two decades, Atomic Force Microscopy (AFM) has emerged as the tool of choice to image living organisms in a near-physiological environment. Whereas fluorescence microscopy techniques allow labeling and tracking of components inside cells and the observation of dynamic processes, AFM is mainly a surface technique that can be operated on a wide range of substrates including biological samples. AFM enables extraction of topographical, mechanical and chemical information from these samples.

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Imaging of the membrane surface of MDCK cells by atomic force microscopy

Cited by 80 publications

References 38 publications

The electrical resistance breakdown assay determines the role of proteinases in tumor cell invasion

The electrical resistance breakdown assay determines the role of proteinases in tumor cell invasion

Structural and Mechanical Heterogeneity of the Erythrocyte Membrane Reveals Hallmarks of Membrane Stability

Atomic Force Microscopy Imaging of Living Cells

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