• Title of article

    Quantifying the contribution of actin networks to the elastic strength of fibroblasts

  • Author/Authors

    Ananthakrishnan، نويسنده , , Revathi and Guck، نويسنده , , Jochen and Wottawah، نويسنده , , Falk and Schinkinger، نويسنده , , Stefan and Lincoln، نويسنده , , Bryan and Romeyke، نويسنده , , Maren and Moon، نويسنده , , Tess and Kنs، نويسنده , , Josef، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2006
  • Pages
    15
  • From page
    502
  • To page
    516
  • Abstract
    The structural models created to understand the cytoskeletal mechanics of cells in suspension are described here. Suspended cells can be deformed by well-defined surface stresses in an Optical Stretcher [Guck, J., Ananthakrishnan, R., Mahmood, H., Moon, T.J., Cunningham, C.C., Käs, J., 2001. The optical stretcher: a novel laser tool to micromanipulate cells. Biophys. J. 81(2), 767–784], a two-beam optical trap designed for the contact-free deformation of cells. Suspended cells have a well-defined cytoskeleton, displaying a radially symmetric actin cortical network underlying the cell membrane with no actin stress fibers, and microtubules and intermediate filaments in the interior. Based on experimental data using suspended fibroblasts, we create two structural models: a thick shell actin cortex model that describes cell deformation for a localized stress distribution on these cells and a three-layered model that considers the entire cytoskeleton when a broad stress distribution is applied. ng the models to data, we obtain a (actin) cortical shear moduli G of ∼220 Pa for normal fibroblasts and ∼185 Pa for malignantly transformed fibroblasts. Additionally, modeling the cortex as a transiently crosslinked isotropic actin network, we show that actin and its crosslinkers must be co-localized into a tight shell to achieve these cortical strengths. The similar moduli values and cortical actin and crosslinker densities but different deformabilities of the normal and cancerous cells suggest that a cellʹs structural strength is not solely determined by cytoskeletal composition but equally importantly by (actin) cytoskeletal architecture via differing cortical thicknesses. We also find that although the interior structural elements (microtubules, nucleus) contribute to the deformed cellʹs exact shape via their loose coupling to the cortex, it is the outer actin cortical shell (and its thickness) that mainly determines the cellʹs structural response.
  • Keywords
    Optical stretcher , fibroblast , Cell model , continuum mechanics , Finite-element simulation
  • Journal title
    Journal of Theoretical Biology
  • Serial Year
    2006
  • Journal title
    Journal of Theoretical Biology
  • Record number

    1537993