Altered mechanical properties of actin fibers due to breast cancer invasion: parameter identification based on micropipette aspiration and multiscale tensegrity modeling (original) (raw)
Kraning-Rush CM, Califano JP, Reinhart-King CA (2012) Cellular traction stresses increase with increasing metastatic potential. PLoS One 7(2):e32572 ArticleCASPubMedPubMed Central Google Scholar
Kassianidou E, Kumar S (2015) A biomechanical perspective on stress fiber structure and function. Biochim Biophys Acta (BBA)-Mol Cell Res 1853(11):3065–3074 ArticleCAS Google Scholar
Zhang J, Wang C (2014) Molecular structural mechanics model for the mechanical properties of microtubules. Biomech Model Mechanobiol 13(6):1175–1184 ArticleCASPubMed Google Scholar
Labouesse C, Gabella C, Meister JJ, Vianay B, Verkhovsky AB (2016) Microsurgery-aided in-situ force probing reveals extensibility and viscoelastic properties of individual stress fibers. Sci Rep 6:23722 ArticleCASPubMedPubMed Central Google Scholar
Costa KD, Hucker WJ, Yin FC (2002) Buckling of actin stress fibers: a new wrinkle in the cytoskeletal tapestry. Cell Motil Cytoskeleton 52(4):266–274 ArticlePubMed Google Scholar
Kojima H, Ishijima A, Yanagida T (1994) Direct measurement of stiffness of single actin filaments with and without tropomyosin by in vitro nanomanipulation. Proc Natl Acad Sci 91(26):12962–12966 ArticleCASPubMed Google Scholar
Kishino A, Yanagida T (1988) Force measurements by micromanipulation of a single actin filament by glass needles. Nature 334(6177):74–76 ArticleCASPubMed Google Scholar
Ebashi S, Ebashi F (1964) A new protein component participating in the superprecipitation of myosin B. J Biochem 55(6):604–613 ArticleCASPubMed Google Scholar
Weber A, Winicur S (1961) The role of calcium in the superprecipitation of actomyosin. J Biol Chem 236(31):g8–g3202 Google Scholar
Spicer SS (1951) Gel formation caused by adenosine triphosphate in actomyosin solutions. J Biol Chem 190(1):257–267 ArticleCASPubMed Google Scholar
Satcher RL Jr, Dewey CF Jr (1996) Theoretical estimates of mechanical properties of the endothelial cell cytoskeleton. Biophys J 71(1):109–118 ArticlePubMedPubMed Central Google Scholar
Li J, Dao M, Lim CT, Suresh S (2005) Spectrin-level modeling of the cytoskeleton and optical tweezers stretching of the erythrocyte. Biophys J 88(5):3707–3719 ArticleCASPubMedPubMed Central Google Scholar
Ladjal H, Hanus JL, Ferreira A (2013) Micro-to-nano biomechanical modeling for assisted biological cell injection. IEEE Trans Biomed Eng 60(9):2461–2471 ArticlePubMed Google Scholar
Stamenović D, Ingber DE (2002) Models of cytoskeletal mechanics of adherent cells. Biomech Model Mechanobiol 1(1):95–108 ArticlePubMed Google Scholar
Stamenovic D, Coughlin MF (2000) A quantitative model of cellular elasticity based on tensegrity. J Biomech Eng 122(1):39–43 ArticleCASPubMed Google Scholar
Canadas P et al (2002) A cellular tensegrity model to analyse the structural viscoelasticity of the cytoskeleton. J Theor Biol 218(2):155–173 ArticlePubMed Google Scholar
Pozo-Guisado E, Alvarez-Barrientos A, Mulero-Navarro S, Santiago-Josefat B, Fernandez-Salguero PM (2002) The antiproliferative activity of resveratrol results in apoptosis in MCF-7 but not in MDA-MB-231 human breast cancer cells: cell-specific alteration of the cell cycle. Biochem Pharmacol 64(9):1375–1386 ArticleCASPubMed Google Scholar
Nematbakhsh Y, Pang KT, Lim CT (2017) Correlating the viscoelasticity of breast cancer cells with their malignancy. Convergent Sci Phys Oncol 3(3):034003 Article Google Scholar
Li QS, Lee GYH, Ong CN, Lim CT (2008) AFM indentation study of breast cancer cells. Biochem Biophys Res Commun 374(4):609–613 ArticleCASPubMed Google Scholar
Guilak F, Alexopoulos LG, Haider MA, Ting-Beall HP, Setton LA (2005) Zonal uniformity in mechanical properties of the chondrocyte pericellular matrix: micropipette aspiration of canine chondrons isolated by cartilage homogenization. Ann Biomed Eng 33(10):1312–1318 ArticlePubMed Google Scholar
Guilak F, Tedrow JR, Burgkart R (2000) Viscoelastic properties of the cell nucleus. Biochem Biophys Res Commun 269(3):781–786 ArticleCASPubMed Google Scholar
Theret DP, Levesque MJ, Sato M, Nerem RM, Wheeler LT (1988) The application of a homogeneous half-space model in the analysis of endothelial cell micropipette measurements. J Biomech Eng 110(3):190–199 ArticleCASPubMed Google Scholar
Yu H, Tay CY, Leong WS, Tan SCW, Liao K, Tan LP (2010) Mechanical behavior of human mesenchymal stem cells during adipogenic and osteogenic differentiation. Biochem Biophys Res Commun 393(1):150–155 ArticleCASPubMed Google Scholar
Tan SC, Pan WX, Ma G, Cai N, Leong KW, Liao K (2008) Viscoelastic behaviour of human mesenchymal stem cells. BMC Cell Biol 9(1):40 ArticlePubMedPubMed Central Google Scholar
Nikkhah M, Strobl JS, de Vita R, Agah M (2010) The cytoskeletal organization of breast carcinoma and fibroblast cells inside three dimensional (3-D) isotropic silicon microstructures. Biomaterials 31(16):4552–4561 ArticleCASPubMed Google Scholar
Stamenović D, Fredberg JJ, Wang N, Butler JP, Ingber DE (1996) A microstructural approach to cytoskeletal mechanics based on tensegrity. J Theor Biol 181(2):125–136 ArticlePubMed Google Scholar
Wendling S, Oddou C, Isabey D (1999) Stiffening response of a cellular tensegrity model. J Theor Biol 196(3):309–325 ArticleCASPubMed Google Scholar
Mohri F, Motro R (1993) Static and kinematic determination of generalized space reticulated systems. Struct Eng Rev 5(3):231–237 Google Scholar
Canadas P et al (2003) Mechanisms governing the visco-elastic responses of living cells assessed by foam and tensegrity models. Med Biol Eng Comput 41(6):733–739 ArticleCASPubMed Google Scholar
Mofrad MR, Kamm RD (2006) Cytoskeletal mechanics: models and measurements in cell mechanics. Cambridge University Press
Khani MM, Tafazzoli-Shadpour M, Rostami M, Peirovi H, Janmaleki M (2014) Evaluation of mechanical properties of human mesenchymal stem cells during differentiation to smooth muscle cells. Ann Biomed Eng 42(7):1373–1380 ArticlePubMed Google Scholar
Pachenari M, Seyedpour SM, Janmaleki M, Shayan SB, Taranejoo S, Hosseinkhani H (2014) Mechanical properties of cancer cytoskeleton depend on actin filaments to microtubules content: investigating different grades of colon cancer cell lines. J Biomech 47(2):373–379 ArticleCASPubMed Google Scholar
Mogilner A, Manhart A (2018) Intracellular fluid mechanics: coupling cytoplasmic flow with active cytoskeletal gel. Annu Rev Fluid Mech 50:347–370 Article Google Scholar
Quinlan ME (2016) Cytoplasmic streaming in the Drosophila oocyte. Annu Rev Cell Dev Biol 32:173–195 ArticleCASPubMed Google Scholar
Gross SR (2013) Actin binding proteins: their ups and downs in metastatic life. Cell Adhes Migr 7(2):199–213 Article Google Scholar
Suresh S (2007) Biomechanics and biophysics of cancer cells. Acta Mater 55(12):3989–4014 ArticleCAS Google Scholar
Kumar S, Weaver VM (2009) Mechanics, malignancy, and metastasis: the force journey of a tumor cell. Cancer Metastasis Rev 28(1–2):113–127 ArticlePubMedPubMed Central Google Scholar
Yilmaz M, Christofori G (2009) EMT, the cytoskeleton, and cancer cell invasion. Cancer Metastasis Rev 28(1–2):15–33 ArticlePubMed Google Scholar
Kemp JP, Brieher WM (2018) The actin filament bundling protein α-actinin-4 actually suppresses actin stress fibers by permitting actin turnover. J Biol Chem 293(37):14520–14533 ArticleCASPubMedPubMed Central Google Scholar
Zhang R et al (2020) Dynamin regulates the dynamics and mechanical strength of the actin cytoskeleton as a multifilament actin-bundling protein. Nat Cell Biol:1–15