by Keyword: Durotaxis
Faure, LM, Gómez-González,, M, Baguer, O, Comelles, J, Martínez, E, Arroyo, M, Trepat, X, Roca-Cusachs, P, (2024). 3D Micropatterned Traction Force Microscopy: A Technique to Control 3D Cell Shape While Measuring Cell-Substrate Force Transmission Advanced Science 11, 2406932 
Cell shape and function are intimately linked, in a way that is mediated by the forces exerted between cells and their environment. The relationship between cell shape and forces has been extensively studied for cells seeded on flat 2D substrates, but not for cells in more physiological 3D settings. Here, a technique called 3D micropatterned traction force microscopy (3D-mu TFM) to confine cells in 3D wells of defined shape, while simultaneously measuring the forces transmitted between cells and their microenvironment is demonstrated. This technique is based on the 3D micropatterning of polyacrylamide wells and on the calculation of 3D traction force from their deformation. With 3D-mu TFM, it is shown that MCF10A breast epithelial cells exert defined, reproducible patterns of forces on their microenvironment, which can be both contractile and extensile. Cells switch from a global contractile to extensile behavior as their volume is reduced are further shown. The technique enables the quantitative study of cell mechanobiology with full access to 3D cellular forces while having accurate control over cell morphology and the mechanical conditions of the microenvironment.
JTD Keywords: Cell volumes, Cytoskeleton, Durotaxis, Micro-wells, Myosi, Reveals, Traction force
Fortunato, IC, Sunyer, R, (2022). The Forces behind Directed Cell Migration Biophysica 2, 548-563
Directed cell migration is an essential building block of life, present when an embryo develops, a dendritic cell migrates toward a lymphatic vessel, or a fibrotic organ fails to restore its normal parenchyma. Directed cell migration is often guided by spatial gradients in a physicochemical property of the cell microenvironment, such as a gradient in chemical factors dissolved in the medium or a gradient in the mechanical properties of the substrate. Single cells and tissues sense these gradients, establish a back-to-front polarity, and coordinate the migration machinery accordingly. Central to these steps we find physical forces. In some cases, these forces are integrated into the gradient sensing mechanism. Other times, they transmit information through cells and tissues to coordinate a collective response. At any time, they participate in the cellular migratory system. In this review, we explore the role of physical forces in gradient sensing, polarization, and coordinating movement from single cells to multicellular collectives. We use the framework proposed by the molecular clutch model and explore to what extent asymmetries in the different elements of the clutch can lead to directional migration.
JTD Keywords: Cell migration, Cell traction forces, Chemotaxis, Contact guidance, Curvotaxis, Cytoskeleton, Durotaxis, Extracellular-matrix, Focal adhesions, Guidance, Haptotaxis, Leading-edge, Mechanotaxis, Membrane tension, Molecular clutch model, Myosin-ii, Reduced inequalities, Rigidity, Stress fibers, Traction
Beedle, AEM, Roca-Cusachs, P, (2022). In search of a softer environment Nature Materials 21, 995-996
By maximizing cell-substrate force transmission, cancer cells can migrate towards either stiffer or softer substrate regions.
JTD Keywords: Durotaxis, Stiffness
