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W tym Artykule

  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

Here, we detail the experimental techniques used to evaluate the protrusion forces that podosomes apply on a compliant film, from the preparation of the film to the automated analysis of topographical images.

Streszczenie

In numerous biological contexts, animal cells need to interact physically with their environment by developing mechanical forces. Among these, traction forces have been well-characterized, but there is a lack of techniques allowing the measurement of the protrusion forces exerted by cells orthogonally to their substrate. We designed an experimental setup to measure the protrusion forces exerted by adherent cells on their substrate. Cells plated on a compliant Formvar sheet deform this substrate and the resulting topography is mapped by atomic force microscopy (AFM) at the nanometer scale. Force values are then extracted from an analysis of the deformation profile based on the geometry of the protrusive cellular structures. Hence, the forces exerted by the individual protruding units of a living cell can be measured over time. This technique will enable the study of force generation and its regulation in the many cellular processes involving protrusion. Here, we describe its application to measure the protrusive forces generated by podosomes formed by human macrophages.

Wprowadzenie

Animal cells interact physically with the matrix and the other cells that constitute their environment1. This is required for them to migrate, internalize bodies, acquire external information, or differentiate. In such processes, the cell must generate mechanical forces and, as numerous studies have shown over the recent years, the ability of a cell to generate forces and probe its environment influences its biological behavior, directing for instance proliferation or differentiation2,3. In turn, the measurement of cellular forces is a major aid to study the regulation of force generation and understand its implication in cell behavior and tissue fate4,5.

Recent years have witnessed the development of numerous techniques to measure the forces that a cell can exert on its environment6. The majority of these have been instrumental in revealing the traction forces that cells exert as they pull on mobile probes or a deformable substrate. However, the mechanical forces involved in protrusion into the extracellular environment suffer from a lack of measurement techniques and are to date not well characterized.

To overcome this limitation, we present a method to measure forces exerted orthogonally to the substrate. It consists in plating living cells on a thin elastic sheet that can deform in the orthogonal direction, making it possible to measure substrate deformation by the cells and deduce the forces involved. Substrate topography is measured with nanoscale resolution using atomic force microscopy and the evaluation of forces from deformation relies on the knowledge of the geometry of the protrusive cellular structures7,8,9.

Here, we describe the setup and its application to measure the forces generated by podosomes, protrusive adhesion structures formed by macrophages for their mesenchymal migration in three-dimensional environments10,11,12,13,14,15,16,17. We believe that this technique will advance the understanding of force generation and its regulation in the many cellular processes involving protrusion.

Protokół

1. Preparation of Formvar-Coated Grids

  1. Clean electron microscopy grids with pure acetone and dry them on filter paper. Then clean a microscope slide with pure ethanol, wipe with a lens paper and remove dust with a blower.
  2. Place an ethanol-cleaned glass slide vertically in the funnel of a film casting device containing a solution of Formvar in the lower part. Cover the top of the funnel.
  3. Pump 100 mL of Formvar solution (0.5% in ethylene dichloride) with the atomizer bulb until the level reaches two thirds of the slide.
  4. Keep the slide in the solution for 1 min.
  5. Open the valve of the device to drain the Formvar solution in a steady stream. A flow rate of 10 to 15 mL/s will yield a Formvar film of 30-80 nm. The thickness of the film is determined by the concentration of the Formvar solution and by the drainage rate.
    NOTE: The drainage rate can be controlled by venting the pressure via the air-out valve by slowly opening the valve. The faster the drainage, the thicker the film. In practice, because it is difficult to predict the film thickness from the Formvar flow rate, we prepare several batches of Formvar films and control their thickness by AFM (see Step 2).
  6. Remove the slide from the chamber and dry it delicately on filter paper to remove any liquid Formvar.
  7. Cut out a 20 mm x 50 mm rectangle from the Formvar film with a razor blade.
  8. Fill a beaker with clean distilled water and slowly plunge the slide vertically into the water to float off the film: the film should float on the water surface.
  9. Place dry acetone-cleaned grids on the film, shiny face up.
  10. Place a round glass coverslip (Ø 12 mm) onto a few of the grids. This coverslip will serve to measure the film thickness (see Step 2).
  11. Cover a microscope slide with a white sticker resized to fit it. Dip the slide vertically at the border of the floating Formvar film until the whole film adheres to the slide. Remove excess water from the slide with filter paper and let it dry at room temperature overnight.

2. Measurement of Film Thickness

  1. Cut the Formvar around the coverslip with tweezers to detach it from the slide.
  2. Mark the location of the grid under the coverslip with a pen.
  3. Cut the Formvar around the marked grid to detach it from the coverslip. There will therefore be a hole in the remaining Formvar sheet, which will allow to measure the film thickness. Cover the coverslip with PBS and place it on a glass slide on the microscope.
  4. Mount a silicon nitride cantilever on the AFM glass block, making sure the golden stripe is not covered by the tip of the spring.
    NOTE: The sensitivity and spring constant of the cantilever should have previously been calibrated in PBS.
  5. Mount the glass block onto the AFM module, and then place the module onto the microscope.
  6. Place the Formvar-coated coverslip on the observation chamber and cover it with 500 µL of PBS.
  7. Scan the border of the hole in the Formvar sheet using AFM in contact mode and a 0.5 nN force set point.
  8. Use the glass coverslip surface as the reference for height measurements, and evaluate the Formvar thickness as the height of the cross-section (perform at least 10 measurements per Formvar batch).

3. Seeding Cells on Grids

  1. Under a sterile hood, put a strip (12 mm x 3 mm) of double-sided adhesive tape on a coverslip.
  2. Cut out a Formvar-coated grid with tweezers and put it upside-down on the adhesive strip (only the rim of the grid needs to be attached to the tape). The Formvar film needs to face the coverslip.
  3. Put this device in a culture well.
  4. Place a 10 µL droplet of RPMI without FCS containing 104 macrophages differentiated from human monocytes16.
    NOTE: Make sure not to touch the grid with the pipette tip to prevent damaging the Formvar coating.
  5. Incubate for 30 min (37 °C, 5% CO2) to let cells adhere.
  6. Fill up the well with 2 mL of RPMI containing 10% FCS.
  7. Incubate the device for 2 h at 37 °C and 5% CO2 to let cells adhere before AFM observation.

4. Topography Measurements of Podosome-Induced Deformations

  1. Stick two strips of doubled-sided adhesive tape on a glass bottom Petri dish.
    NOTE: The distance between the two strips should be smaller than the grid diameter.
  2. Carefully detach the grid plated with macrophages from the adhesive tape.
  3. Turn the grid upside-down in order to have the cells facing the glass and stick the grid between the two adhesive strips.
  4. Fix the grid with two new strips of doubled-sided adhesive: the grid will thus be sandwiched between two adhesive strips, leaving the central area of the grid accessible to the AFM tip.
    NOTE: Make sure that the grid is well fixed and not twisted; otherwise the AFM cantilever might not be able to approach the Formvar surface.
  5. Fill the Petri dish with 2 mL of pre-heated 37 °C culture medium (RPMI with 10% FCS) supplemented with 10 mM HEPES (pH 7.4).
  6. Place the culture dish on a 37 °C dish heater.
  7. Install the dish heater on the AFM stage.
  8. Let the system stabilize at 37 °C.
  9. In contact mode with a 0.5 nN force, make a first global image to locate podosomes, and then scan the Formvar topography at 3 Hz with an approximately 20 nm-large pixel.
    NOTE: Avoid scanning near the edges of the grid.

Wyniki

The above protocol describes how to prepare the experimental setup to quantify protrusion forces applied by macrophage podosomes on a Formvar substrate. This is achieved using AFM and is illustrated in Figure 1.

When analyzing a topographical image of bulges beneath podosomes using the JPK data processing software, a third-degree polynomial fit should be subtracted from each scan line independently....

Dyskusje

Material properties

The choice of the material for the deformable membrane, in our case Formvar, needs to fulfill a few requirements. The material must be transparent to visible light and exhibit limited auto fluorescence to allow observations in bright field and fluorescence microscopy. The roughness of the thin film must be well below 10 nm to avoid any topographical effect on cell adhesion and to allow clear observation of the cell-induced protrusions by AFM imaging. Finall...

Ujawnienia

No conflicts of interest declared.

Podziękowania

The authors are grateful to Anna Labernadie, Guillaume Charrière and Patrick Delobelle for their initial contribution to this work and to Matthieu Sanchez and Françoise Viala for their help with video filming and editing. This work has been supported by l'Agence Nationale de la Recherche (ANR14-CE11-0020-02), la Fondation pour la Recherche Médicale (FRM DEQ2016 0334894), INSERM Plan Cancer, Fondation Toulouse Cancer and Human Frontier Science Program (RGP0035/2016).

Materiały

NameCompanyCatalog NumberComments
200 mesh nickel gridsElectron Microscopy SciencesG200-Ni
Filter paperSigma-Aldrich1001-055
Microscope slidesFisher Scientific10235612
White stickers 26 x 70 mmAveryDP033-100
Film casting device with valve in its outletElectron Microscopy Sciences71305-01
RazorbladesElectron Microscopy Sciences72000
EthanolVWR1.08543.0250
AcetoneVWR20066.321
Formvar 0.5% solution in ethylene dichlorideElectron Microscopy Sciences15820
12 mm coverslipsVWR631-0666
Inverted microscopeCarl ZeissAxiovert 200
Atomic Force MicroscopeJPK InstrumentsNanoWizard III
Temperature-controlled sample holder JPK InstrumentsBioCell
Silicon nitride cantilever with a nominal spring constant of 0.01 N/mVeeco InstrumentsMLCT-AUHW
PBSGibco14190-094
Double-sided adhesive tapeAPLI AGIPA118100
RPMI 1640Gibco31870-025
FCSSigma-AldrichF7524
HEPES Sigma-AldrichH0887
35 mm glass-bottom Petri dishesWPIFD35-100

Odniesienia

  1. Discher, D. E., Janmey, P., Wang, Y. L. Tissue Cells Feel and Respond to the Stiffness of Their Substrate. Science. 310, 1139-1143 (2005).
  2. Paszek, M. J., et al. Tensional Homeostasis and the Malignant Phenotype. Cancer Cell. 8, 241-254 (2005).
  3. Engler, A. J., Sen, S., Sweeney, H. L., Discher, D. E. Matrix Elasticity Directs Stem Cell Lineage Specification. Cell. 126, 677-689 (2006).
  4. Gilbert, P. M., Weaver, V. M. Cellular Adaptation to Biomechanical Stress across Length Scales in Tissue Homeostasis and Disease. Seminars in Cell & Developmental Biology. 67, 141-152 (2017).
  5. Vining, K. H., Mooney, D. J. Mechanical Forces Direct Stem Cell Behaviour in Development and Regeneration. Nature Reviews Molecular Cell Biology. , (2017).
  6. Roca-Cusachs, P., Conte, V., Trepat, X. Quantifying Forces in Cell Biology. Nature Cell Biology. 19, 742-751 (2017).
  7. Labernadie, A., et al. Protrusion Force Microscopy Reveals Oscillatory Force Generation and Mechanosensing Activity of Human Macrophage Podosomes. Nature Communications. 5, 5343 (2014).
  8. Proag, A., et al. Working Together: Spatial Synchrony in the Force and Actin Dynamics of Podosome First Neighbors. ACS Nano. 9, 3800-3813 (2015).
  9. Proag, A., Bouissou, A., Vieu, C., Maridonneau-Parini, I., Poincloux, R. Evaluation of the Force and Spatial Dynamics of Macrophage Podosomes by Multi-Particle Tracking. Methods. 94, 75-84 (2016).
  10. Cougoule, C., et al. Three-Dimensional Migration of Macrophages Requires Hck for Podosome Organization and Extracellular Matrix Proteolysis. Blood. 115, 1444-1452 (2010).
  11. Cougoule, C., et al. Blood Leukocytes and Macrophages of Various Phenotypes Have Distinct Abilities to Form Podosomes and to Migrate in 3d Environments. European Journal of Cell Biology. 91, 938-949 (2012).
  12. Guiet, R., et al. Macrophage Mesenchymal Migration Requires Podosome Stabilization by Filamin A. Journal of Biological Chemistry. 287, 13051-13062 (2012).
  13. Maridonneau-Parini, I. Control of Macrophage 3d Migration: A Therapeutic Challenge to Limit Tissue Infiltration. Immunology Review. 262, 216-231 (2014).
  14. Park, H., et al. Tyrosine Phosphorylation of Wiskott-Aldrich Syndrome Protein (Wasp) by Hck Regulates Macrophage Function. Journal of Biological Chemistry. 289, 7897-7906 (2014).
  15. Van Goethem, E., et al. Macrophage Podosomes Go 3d. European Journal of Cell Biology. 90, 224-236 (2011).
  16. Van Goethem, E., Poincloux, R., Gauffre, F., Maridonneau-Parini, I., Le Cabec, V. Matrix Architecture Dictates Three-Dimensional Migration Modes of Human Macrophages: Differential Involvement of Proteases and Podosome-Like Structures. Journal of Immunology. 184, 1049-1061 (2010).
  17. Verollet, C., et al. Hiv-1 Reprograms the Migration of Macrophages. Blood. 125, 1611-1622 (2015).
  18. Bouissou, A., et al. Podosome Force Generation Machinery: A Local Balance between Protrusion at the Core and Traction at the Ring. ACS Nano. 11, 4028-4040 (2017).
  19. Lizarraga, F., et al. Diaphanous-Related Formins Are Required for Invadopodia Formation and Invasion of Breast Tumor Cells. Cancer Research. 69, 2792-2800 (2009).
  20. Carman, C. V., et al. Transcellular Diapedesis Is Initiated by Invasive Podosomes. Immunity. 26, 784-797 (2007).
  21. Sage, P. T., et al. Antigen Recognition Is Facilitated by Invadosome-Like Protrusions Formed by Memory/Effector T Cells. Journal of Immunology. 188, 3686-3699 (2012).
  22. Sens, K. L., et al. An Invasive Podosome-Like Structure Promotes Fusion Pore Formation During Myoblast Fusion. Journal of Cell Biology. 191, 1013-1027 (2010).
  23. Takito, J., et al. The Transient Appearance of Zipper-Like Actin Superstructures During the Fusion of Osteoclasts. Journal of Cell Science. 125, 662-672 (2012).
  24. Shilagardi, K., et al. Actin-Propelled Invasive Membrane Protrusions Promote Fusogenic Protein Engagement During Cell-Cell Fusion. Science. 340, 359-363 (2013).
  25. Freeman, S. A., et al. Integrins Form an Expanding Diffusional Barrier That Coordinates Phagocytosis. Cell. 164, 128-140 (2016).

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Keywords Protrusion Force MicroscopyAtomic Force MicroscopyCell ProtrusionsFormvar FilmCell AdhesionPodosomesMechanical ModelFilm Thickness MeasurementContact Mode AFM

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