Vimentin Intermediate Filaments Can Enhance or Abate Active Cellular Forces in a Microenvironmental Stiffness-Dependent Manner

The mechanical properties of cells are largely determined by the cytoskeleton, which is a complex network of interconnected biopolymers consisting of actin filaments, microtubules, and intermediate filaments. While disruption of the actin filament and microtubule networks is known to decrease and increase cell-generated forces, respectively, the effect of intermediate filaments on cellular forces is not well understood. Using a combination of theoretical modeling and experiments, we show that disruption of vimentin intermediate filaments can either increase or decrease cell-generated forces, depending on microenvironment stiffness, reconciling seemingly opposite results in the literature. On the one hand, vimentin is involved in the transmission of actomyosin-based tensile forces to the matrix and therefore enhances traction forces. On the other hand, vimentin reinforces microtubules and their stability under compression, thus promoting the role of microtubules in suppressing cellular traction forces. We show that the competition between these two opposing effects of vimentin is regulated by the microenvironment stiffness. For low matrix stiffness, the force-transmitting role of vimentin dominates over their microtubule-reinforcing role and therefore vimentin increases traction forces. At high matrix stiffness, vimentin decreases traction forces as the microtubule-reinforcing role of vimentin becomes more important with increasing matrix stiffness. Our theory reconciles seemingly disparate experimental observations on the role of vimentin in active cellular forces and provides a unified description of stiffness-dependent chemo-mechanical regulation of cell contractility by vimentin. Significance Vimentin is a marker of the epithelial to mesenchymal transition which takes place during important biological processes including embryogenesis, metastasis, tumorigenesis, fibrosis, and wound healing. While the roles of the actin and microtubule networks in the transmission of cellular forces to the extracellular matrix are known, it is not clear how vimentin intermediate filaments impact cellular forces. Here, we show that vimentin impacts cellular forces in a matrix stiffness-dependent manner. Disruption of vimentin in cells on soft matrices reduces cellular forces, while it increases cellular forces in cells on stiff matrices. Given that cellular forces are central to both physiological and pathological processes, our study has broad implications for understanding the effect of vimentin on cellular forces in different microenvironments.

[1]  J. Fredberg,et al.  Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortex , 2021, bioRxiv.

[2]  M. Bonn,et al.  Tension Causes Unfolding of Intracellular Vimentin Intermediate Filaments , 2020, Advanced biosystems.

[3]  Michael J Rust,et al.  Myosin-driven actin-microtubule networks exhibit self-organized contractile dynamics , 2020, Science Advances.

[4]  S. Köster,et al.  Vimentin intermediate filaments stabilize dynamic microtubules by direct interactions , 2020, Nature Communications.

[5]  G. Genin,et al.  The Balance between Actomyosin Contractility and Microtubule Polymerization Regulates Hierarchical Protrusions That Govern Efficient Fibroblast-Collagen Interactions. , 2020, ACS nano.

[6]  S. Cai,et al.  High stretchability, strength, and toughness of living cells enabled by hyperelastic vimentin intermediate filaments , 2019, Proceedings of the National Academy of Sciences.

[7]  G. Shivashankar,et al.  Regulation of nuclear architecture, mechanics, and nucleocytoplasmic shuttling of epigenetic factors by cell geometric constraints , 2019, Proceedings of the National Academy of Sciences.

[8]  B. Hinz,et al.  Dynamic fibroblast contractions attract remote macrophages in fibrillar collagen matrix , 2019, Nature Communications.

[9]  J. Fredberg,et al.  Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness. , 2019, Biophysical journal.

[10]  H. Herrmann Faculty Opinions recommendation of Vimentin intermediate filaments template microtubule networks to enhance persistence in cell polarity and directed migration. , 2018, Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature.

[11]  Sean X. Sun,et al.  Cell tension and mechanical regulation of cell volume , 2018, Molecular biology of the cell.

[12]  G. Koenderink,et al.  Actin–microtubule crosstalk in cell biology , 2018, Nature Reviews Molecular Cell Biology.

[13]  C. Oomens,et al.  The Mechanical Contribution of Vimentin to Cellular Stress Generation. , 2018, Journal of biomechanical engineering.

[14]  E. Peterman,et al.  Viscoelastic properties of vimentin originate from nonequilibrium conformational changes , 2018, Science Advances.

[15]  Cécile Leduc,et al.  Intermediate filaments control collective migration by restricting traction forces and sustaining cell–cell contacts , 2018, bioRxiv.

[16]  Sangyoon J. Han,et al.  Vimentin fibers orient traction stress , 2017, Proceedings of the National Academy of Sciences.

[17]  G. Shivashankar,et al.  Cell geometry dictates TNFα-induced genome response , 2017, Proceedings of the National Academy of Sciences.

[18]  R. Krishnan,et al.  Vimentin intermediate filaments control actin stress fiber assembly through GEF-H1 and RhoA , 2017, Journal of Cell Science.

[19]  Xinzeng Feng,et al.  Fibrous nonlinear elasticity enables positive mechanical feedback between cells and ECMs , 2016, Proceedings of the National Academy of Sciences.

[20]  Vivek B. Shenoy,et al.  A chemo-mechanical free-energy-based approach to model durotaxis and extracellular stiffness-dependent contraction and polarization of cells , 2016, Interface Focus.

[21]  S. Rosenfeld,et al.  Matrix-driven Myosin II Mediates the Pro-fibrotic Fibroblast Phenotype* , 2016, The Journal of Biological Chemistry.

[22]  R. Goldman,et al.  Intermediate Filaments Play a Pivotal Role in Regulating Cell Architecture and Function* , 2015, The Journal of Biological Chemistry.

[23]  Cécile Leduc,et al.  Intermediate filaments in cell migration and invasion: the unusual suspects. , 2015, Current opinion in cell biology.

[24]  G. Koenderink,et al.  Cytoskeletal crosstalk: when three different personalities team up. , 2015, Current Opinion in Cell Biology.

[25]  M. Balland,et al.  Cell dipole behaviour revealed by ECM sub-cellular geometry , 2014, Nature Communications.

[26]  David J Mooney,et al.  Extracellular matrix stiffness and composition jointly regulate the induction of malignant phenotypes in mammary epithelium. , 2014, Nature materials.

[27]  Kenneth M. Yamada,et al.  Generation of compartmentalized pressure by a nuclear piston governs cell motility in a 3D matrix , 2014, Science.

[28]  M Cristina Marchetti,et al.  Geometry regulates traction stresses in adherent cells. , 2014, Biophysical journal.

[29]  Paul A. Janmey,et al.  Vimentin enhances cell elastic behavior and protects against compressive stress. , 2014, Biophysical journal.

[30]  M. Mrksich,et al.  Geometric control of vimentin intermediate filaments. , 2014, Biomaterials.

[31]  David A Weitz,et al.  The role of vimentin intermediate filaments in cortical and cytoplasmic mechanics. , 2013, Biophysical journal.

[32]  K. Ridge,et al.  The role of vimentin intermediate filaments in the progression of lung cancer. , 2013, American journal of respiratory cell and molecular biology.

[33]  K. Burridge,et al.  The tension mounts: Stress fibers as force-generating mechanotransducers , 2013, The Journal of cell biology.

[34]  M. Gardel,et al.  F-actin buckling coordinates contractility and severing in a biomimetic actomyosin cortex , 2012, Proceedings of the National Academy of Sciences.

[35]  K. Burridge,et al.  From mechanical force to RhoA activation. , 2012, Biochemistry.

[36]  Yu-Li Wang,et al.  Microtubule depolymerization induces traction force increase through two distinct pathways , 2011, Journal of Cell Science.

[37]  Thomas Boudou,et al.  A hitchhiker's guide to mechanobiology. , 2011, Developmental cell.

[38]  Erin L. Doyle,et al.  Efficient design and assembly of custom TALEN and other TAL effector-based constructs for DNA targeting , 2011, Nucleic acids research.

[39]  Jianping Fu,et al.  Cell shape and substrate rigidity both regulate cell stiffness. , 2011, Biophysical journal.

[40]  Yu-Li Wang,et al.  The regulation of traction force in relation to cell shape and focal adhesions. , 2011, Biomaterials.

[41]  Wesley R. Legant,et al.  Measurement of mechanical tractions exerted by cells in three-dimensional matrices , 2010, Nature Methods.

[42]  M. Sokabe,et al.  Sensing substrate rigidity by mechanosensitive ion channels with stress fibers and focal adhesions. , 2010, Current opinion in cell biology.

[43]  D. Ingber,et al.  Ultra-rapid activation of TRPV4 ion channels by mechanical forces applied to cell surface beta1 integrins. , 2010, Integrative biology : quantitative biosciences from nano to macro.

[44]  R. Goldman,et al.  Vimentin induces changes in cell shape, motility, and adhesion during the epithelial to mesenchymal transition , 2010, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[45]  C. Broedersz,et al.  Origins of elasticity in intermediate filament networks. , 2010, Physical review letters.

[46]  Paul A. Janmey,et al.  Non-Linear Elasticity of Extracellular Matrices Enables Contractile Cells to Communicate Local Position and Orientation , 2009, PloS one.

[47]  Ning Wang,et al.  Plectin contributes to mechanical properties of living cells. , 2009, American journal of physiology. Cell physiology.

[48]  S. Bhattacharya,et al.  Dominant cataract formation in association with a vimentin assembly disrupting mutation. , 2009, Human molecular genetics.

[49]  B. Hinz,et al.  Myofibroblast communication is controlled by intercellular mechanical coupling , 2008, Journal of Cell Science.

[50]  Marion Ghibaudo,et al.  Traction forces and rigidity sensing regulate cell functions , 2008 .

[51]  G. Bokoch,et al.  GEF-H1 couples nocodazole-induced microtubule disassembly to cell contractility via RhoA. , 2008, Molecular biology of the cell.

[52]  Alain Richert,et al.  Cell stiffening in response to external stress is correlated to actin recruitment. , 2008, Biophysical journal.

[53]  Kheya Sengupta,et al.  Fibroblast adaptation and stiffness matching to soft elastic substrates. , 2007, Biophysical journal.

[54]  Areum Kim,et al.  Microtubule regulation of corneal fibroblast morphology and mechanical activity in 3-D culture. , 2007, Experimental eye research.

[55]  Markus J. Buehler,et al.  Superelasticity, energy dissipation and strain hardening of vimentin coiled-coil intermediate filaments: atomistic and continuum studies , 2007, Journal of Materials Science.

[56]  Yiider Tseng,et al.  A Direct Interaction between Actin and Vimentin Filaments Mediated by the Tail Domain of Vimentin* , 2006, Journal of Biological Chemistry.

[57]  S. Sen,et al.  Matrix Elasticity Directs Stem Cell Lineage Specification , 2006, Cell.

[58]  Donald E. Ingber,et al.  Jcb: Article Introduction , 2002 .

[59]  Eric Mazur,et al.  Viscoelastic retraction of single living stress fibers and its impact on cell shape, cytoskeletal organization, and extracellular matrix mechanics. , 2006, Biophysical journal.

[60]  David A. Schultz,et al.  A mechanosensory complex that mediates the endothelial cell response to fluid shear stress , 2005, Nature.

[61]  Keith Burridge,et al.  Simultaneous stretching and contraction of stress fibers in vivo. , 2004, Molecular biology of the cell.

[62]  Marileen Dogterom,et al.  Dynamic instability of microtubules is regulated by force , 2003, The Journal of cell biology.

[63]  W. Petroll,et al.  Direct correlation of collagen matrix deformation with focal adhesion dynamics in living corneal fibroblasts , 2003, Journal of Cell Science.

[64]  Christopher S. Chen,et al.  Cells lying on a bed of microneedles: An approach to isolate mechanical force , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[65]  Dimitrije Stamenović,et al.  Cell prestress. II. Contribution of microtubules. , 2002, American journal of physiology. Cell physiology.

[66]  Ben Fabry,et al.  Traction fields, moments, and strain energy that cells exert on their surroundings. , 2002, American journal of physiology. Cell physiology.

[67]  D. Ingber,et al.  Mechanical behavior in living cells consistent with the tensegrity model , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[68]  K. Kaibuchi,et al.  Rho-Kinase–Mediated Contraction of Isolated Stress Fibers , 2001, The Journal of cell biology.

[69]  E. Elson,et al.  Effects of cytochalasin D and latrunculin B on mechanical properties of cells. , 2001, Journal of cell science.

[70]  G. Wiche,et al.  Not just scaffolding: plectin regulates actin dynamics in cultured cells. , 1998, Genes & development.

[71]  K. Fujiwara,et al.  Isolation and contraction of the stress fiber. , 1998, Molecular biology of the cell.

[72]  D. Ingber,et al.  Impaired mechanical stability, migration and contractile capacity in vimentin-deficient fibroblasts. , 1998, Journal of cell science.

[73]  P. Janmey,et al.  Interaction of vimentin with actin and phospholipids. , 1998, The Biological bulletin.

[74]  B. Yurke,et al.  Measurement of the force-velocity relation for growing microtubules. , 1997, Science.

[75]  T. Svitkina,et al.  Plectin sidearms mediate interaction of intermediate filaments with microtubules and other components of the cytoskeleton , 1996, The Journal of cell biology.

[76]  K. Burridge,et al.  Rho-stimulated contractility drives the formation of stress fibers and focal adhesions , 1996, The Journal of cell biology.

[77]  E. Elson,et al.  Contraction due to microtubule disruption is associated with increased phosphorylation of myosin regulatory light chain. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[78]  E. Elson,et al.  Correlation of myosin light chain phosphorylation with isometric contraction of fibroblasts. , 1993, The Journal of biological chemistry.

[79]  B A Danowski,et al.  Fibroblast contractility and actin organization are stimulated by microtubule inhibitors. , 1989, Journal of cell science.

[80]  A. Harris,et al.  Silicone rubber substrata: a new wrinkle in the study of cell locomotion. , 1980, Science.

[81]  P. Friedl,et al.  Mechanoreciprocity in cell migration , 2017, Nature Cell Biology.

[82]  Colby G Starker,et al.  Vimentin Intermediate Filaments Template Microtubule Networks to Enhance Persistence in Cell Polarity and Directed Migration. , 2016, Cell systems.