scholarly journals Contractile dynamics change before morphological cues during fluorescence illumination

2015 ◽  
Vol 5 (1) ◽  
Author(s):  
S. G. Knoll ◽  
W. W. Ahmed ◽  
T. A. Saif
Keyword(s):  
Morphological Changes ◽  
Traction Force ◽  
Live Cells ◽  
Excitation Light ◽  
Cell Contractility ◽  
Force Dynamics ◽  
Force Relaxation ◽  
Morphological Cues ◽  
Contractile Forces ◽  
Cell Force

Abstract Illumination can have adverse effects on live cells. However, many experiments, e.g. traction force microscopy, rely on fluorescence microscopy. Current methods to assess undesired photo-induced cell changes rely on qualitative observation of changes in cell morphology. Here we utilize a quantitative technique to identify the effect of light on cell contractility prior to morphological changes. Fibroblasts were cultured on soft elastic hydrogels embedded with fluorescent beads. The adherent cells generated contractile forces that deform the substrate. Beads were used as fiducial markers to quantify the substrate deformation over time, which serves as a measure of cell force dynamics. We find that cells exposed to moderate fluorescence illumination (λ = 540–585 nm, I = 12.5 W/m2, duration = 60 s) exhibit rapid force relaxation. Strikingly, cells exhibit force relaxation after only 2 s of exposure, suggesting that photo-induced relaxation occurs nearly immediately. Evidence of photo-induced morphological changes were not observed for 15–30 min after illumination. Force relaxation and morphological changes were found to depend on wavelength and intensity of excitation light. This study demonstrates that changes in cell contractility reveal evidence of a photo-induced cell response long before any morphological cues.

Simultaneous Measurement of Morphology and Traction Forces of Endothelial Cells Under Fluid Shear Stress

2012 ◽  
Author(s):  
Toshiro Ohashi ◽  
Yusaku Niida ◽  
Ryoichi Tanaka ◽  
Masaaki Sato
Keyword(s):  
Endothelial Cells ◽  
Shear Stress ◽  
Fluid Shear Stress ◽  
Vascular Endothelial Cells ◽  
Morphological Changes ◽  
Traction Force ◽  
Flow Chamber ◽  
Fluid Shear ◽  
Traction Forces ◽  
Contractile Forces

Under fluid shear stress, vascular endothelial cells (ECs) cultured in a monolayer are known to exhibit marked elongation and orientation to the direction of flow [1]. It is also observed that intracellular F-actin filament distributions changed depending on the amplitude of shear stress and the direction of flow, suggesting morphology of ECs is closely related to cytoskeltal structure [2]. ECs generate contractile forces by the actin-myosin machinery and the forces are transmitted to underlying substrate as cellular traction forces. We hypothesize that reorganization of cytoskeletal structures regulates traction forces in ECs exposed to fluid shear stress. In order to measure traction forces and cell morphology simultaneously, we have developed a newly designed flow-imposed device in which a substrate with arrays of elastomeric micropillars (3 μm in diameter and 10 μm in height) is integrated on the bottom of a parallel plate flow chamber. In this study, traction force distributions and morphological changes in GFP-tagged ECs in a monolayer under fluid flow are simultaneously evaluated through image analysis in a spatial and a temporal manner.

scholarly journals Variation in traction forces during cell cycle progression

2017 ◽  
Author(s):  
Benoit Vianay ◽  
Fabrice Senger ◽  
Simon Alamos ◽  
Maya Anjur-Dietrich ◽  
Elizabeth Bearce ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Cell Cycle Progression ◽  
Traction Force ◽  
Traction Forces ◽  
Cycle Progression ◽  
Cell Contractility ◽  
Dividing Cells ◽  
A Cell ◽  
Contractile Forces ◽  
The Impact

AbstractTissue morphogenesis results from the interplay between cell growth and mechanical forces. While the impact of forces on cell proliferation has been fairly well characterized, the inverse relationship is much less understood. Here we investigated how traction forces vary during cell cycle progression. Cell shape was constrained on micropatterned substrates in order to distinguish variations in cell contractility from cell size increase. We performed traction force measurements of asynchronously dividing cells expressing a cell-cycle reporter, to obtain measurements of contractile forces generated during cell division. We found that forces tend to increase as cells progress through G1, before reaching a plateau in S phase, and then decline during G2. This biphasic behaviour revealed a previously undocumented specific and opposite regulation of cell contractility during each cell cycle stage.

A Small Molecule – Protein Hybrid for Voltage Imaging via Quenching of Bioluminescence

2020 ◽  
Author(s):  
Brittany Benlian ◽  
Pavel Klier ◽  
Kayli Martinez ◽  
Marie Schwinn ◽  
Thomas Kirkland ◽  
...  
Keyword(s):  
Energy Transfer ◽  
Membrane Potential ◽  
Small Molecule ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Live Cells ◽  
Potential Oscillations ◽  
Excitation Light ◽  
Voltage Imaging ◽  
Induced Pluripotent

<p>We report a small molecule enzyme pair for optical voltage sensing via quenching of bioluminescence. This <u>Q</u>uenching <u>B</u>ioluminescent V<u>olt</u>age Indicator, or Q-BOLT, pairs the dark absorbing, voltage-sensitive dipicrylamine with membrane-localized bioluminescence from the luciferase NanoLuc (NLuc). As a result, bioluminescence is quenched through resonance energy transfer (QRET) as a function of membrane potential. Fusion of HaloTag to NLuc creates a two-acceptor bioluminescence resonance energy transfer (BRET) system when a tetramethylrhodamine (TMR) HaloTag ligand is ligated to HaloTag. In this mode, Q-BOLT is capable of providing direct visualization of changes in membrane potential in live cells via three distinct readouts: change in QRET, BRET, and the ratio between bioluminescence emission and BRET. Q-BOLT can provide up to a 29% change in bioluminescence (ΔBL/BL) and >100% ΔBRET/BRET per 100 mV change in HEK 293T cells, without the need for excitation light. In cardiac monolayers derived from human induced pluripotent stem cells (hiPSC), Q-BOLT readily reports on membrane potential oscillations. Q-BOLT is the first example of a hybrid small molecule – protein voltage indicator that does not require excitation light and may be useful in contexts where excitation light is limiting.</p> <p> </p>

A Small Molecule – Protein Hybrid for Voltage Imaging via Quenching of Bioluminescence

2020 ◽  
Author(s):  
Brittany Benlian ◽  
Pavel Klier ◽  
Kayli Martinez ◽  
Marie Schwinn ◽  
Thomas Kirkland ◽  
...  
Keyword(s):  
Energy Transfer ◽  
Membrane Potential ◽  
Small Molecule ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Live Cells ◽  
Potential Oscillations ◽  
Excitation Light ◽  
Voltage Imaging ◽  
Induced Pluripotent

<p>We report a small molecule enzyme pair for optical voltage sensing via quenching of bioluminescence. This <u>Q</u>uenching <u>B</u>ioluminescent V<u>olt</u>age Indicator, or Q-BOLT, pairs the dark absorbing, voltage-sensitive dipicrylamine with membrane-localized bioluminescence from the luciferase NanoLuc (NLuc). As a result, bioluminescence is quenched through resonance energy transfer (QRET) as a function of membrane potential. Fusion of HaloTag to NLuc creates a two-acceptor bioluminescence resonance energy transfer (BRET) system when a tetramethylrhodamine (TMR) HaloTag ligand is ligated to HaloTag. In this mode, Q-BOLT is capable of providing direct visualization of changes in membrane potential in live cells via three distinct readouts: change in QRET, BRET, and the ratio between bioluminescence emission and BRET. Q-BOLT can provide up to a 29% change in bioluminescence (ΔBL/BL) and >100% ΔBRET/BRET per 100 mV change in HEK 293T cells, without the need for excitation light. In cardiac monolayers derived from human induced pluripotent stem cells (hiPSC), Q-BOLT readily reports on membrane potential oscillations. Q-BOLT is the first example of a hybrid small molecule – protein voltage indicator that does not require excitation light and may be useful in contexts where excitation light is limiting.</p> <p> </p>

scholarly journals Dissipation of contractile forces: the missing piece in cell mechanics

2017 ◽  
Vol 28 (14) ◽  
pp. 1825-1832 ◽  
Author(s):  
Laetitia Kurzawa ◽  
Benoit Vianay ◽  
Fabrice Senger ◽  
Timothée Vignaud ◽  
Laurent Blanchoin ◽  
...  
Keyword(s):  
Cell Mechanics ◽  
Force Production ◽  
Traction Force ◽  
Structural Rearrangements ◽  
Force Transmission ◽  
Traction Forces ◽  
Cell Traction Forces ◽  
Cell Traction ◽  
Contractile Forces ◽  
Fiber Contraction

Mechanical forces are key regulators of cell and tissue physiology. The basic molecular mechanism of fiber contraction by the sliding of actin filament upon myosin leading to conformational change has been known for decades. The regulation of force generation at the level of the cell, however, is still far from elucidated. Indeed, the magnitude of cell traction forces on the underlying extracellular matrix in culture is almost impossible to predict or experimentally control. The considerable variability in measurements of cell-traction forces indicates that they may not be the optimal readout to properly characterize cell contractile state and that a significant part of the contractile energy is not transferred to cell anchorage but instead is involved in actin network dynamics. Here we discuss the experimental, numerical, and biological parameters that may be responsible for the variability in traction force production. We argue that limiting these sources of variability and investigating the dissipation of mechanical work that occurs with structural rearrangements and the disengagement of force transmission is key for further understanding of cell mechanics.

scholarly journals Collective forces of tumor spheroids in three-dimensional biopolymer networks

eLife ◽  
2020 ◽  
Vol 9 ◽  
Author(s):  
Christoph Mark ◽  
Thomas J Grundy ◽  
Pamela L Strissel ◽  
David Böhringer ◽  
Nadine Grummel ◽  
...  
Keyword(s):  
Single Cells ◽  
Three Dimensional ◽  
Traction Force ◽  
Tumor Spheroids ◽  
Scale Invariant ◽  
Tissue Samples ◽  
Force Microscopy ◽  
Surrounding Matrix ◽  
Highly Nonlinear ◽  
Contractile Forces

We describe a method for quantifying the contractile forces that tumor spheroids collectively exert on highly nonlinear three-dimensional collagen networks. While three-dimensional traction force microscopy for single cells in a nonlinear matrix is computationally complex due to the variable cell shape, here we exploit the spherical symmetry of tumor spheroids to derive a scale-invariant relationship between spheroid contractility and the surrounding matrix deformations. This relationship allows us to directly translate the magnitude of matrix deformations to the total contractility of arbitrarily sized spheroids. We show that our method is accurate up to strains of 50% and remains valid even for irregularly shaped tissue samples when considering only the deformations in the far field. Finally, we demonstrate that collective forces of tumor spheroids reflect the contractility of individual cells for up to 1 hr after seeding, while collective forces on longer timescales are guided by mechanical feedback from the extracellular matrix.

scholarly journals Force localization modes in dynamic epithelial colonies

2018 ◽  
Vol 29 (23) ◽  
pp. 2835-2847 ◽  
Author(s):  
Erik N. Schaumann ◽  
Michael F. Staddon ◽  
Margaret L. Gardel ◽  
Shiladitya Banerjee
Keyword(s):  
Cancer Metastasis ◽  
Wide Spectrum ◽  
Traction Force ◽  
Cellular Motility ◽  
Force Transmission ◽  
Mechanical Coupling ◽  
Cell Behaviors ◽  
Force Dynamics ◽  
Epithelial Tissues ◽  
Cell Matrix Interactions

Collective cell behaviors, including tissue remodeling, morphogenesis, and cancer metastasis, rely on dynamics among cells, their neighbors, and the extracellular matrix. The lack of quantitative models precludes understanding of how cell–cell and cell–matrix interactions regulate tissue-scale force transmission to guide morphogenic processes. We integrate biophysical measurements on model epithelial tissues and computational modeling to explore how cell-level dynamics alter mechanical stress organization at multicellular scales. We show that traction stress distribution in epithelial colonies can vary widely for identical geometries. For colonies with peripheral localization of traction stresses, we recapitulate previously described mechanical behavior of cohesive tissues with a continuum model. By contrast, highly motile cells within colonies produce traction stresses that fluctuate in space and time. To predict the traction force dynamics, we introduce an active adherent vertex model (AAVM) for epithelial monolayers. AAVM predicts that increased cellular motility and reduced intercellular mechanical coupling localize traction stresses in the colony interior, in agreement with our experimental data. Furthermore, the model captures a wide spectrum of localized stress production modes that arise from individual cell activities including cell division, rotation, and polarized migration. This approach provides a robust quantitative framework to study how cell-scale dynamics influence force transmission in epithelial tissues.

scholarly journals Force localization modes in dynamic epithelial colonies

2018 ◽  
Author(s):  
Erik N. Schaumann ◽  
Michael F. Staddon ◽  
Margaret L. Gardel ◽  
Shiladitya Banerjee
Keyword(s):  
Cancer Metastasis ◽  
Wide Spectrum ◽  
Computational Modelling ◽  
Traction Force ◽  
Cellular Motility ◽  
Force Transmission ◽  
Mechanical Coupling ◽  
Cell Behaviors ◽  
Force Dynamics ◽  
Epithelial Tissues

AbstractCollective cell behaviors, including tissue remodeling, morphogenesis and cancer metastasis rely on dynamics between cells, their neighbors and the extracellular matrix. The lack of quantitative models precludes understanding of how cell-cell and cell-matrix interactions regulate tissue-scale force transmission to guide morphogenic processes. We integrate biophysical measurements on model epithelial tissues and computational modelling to explore how cell-level dynamics alter mechanical stress organization at multicellular scales. We show that traction stress distribution in epithelial colonies can vary widely for identical geometries. For colonies with peripheral localization of traction stresses, we recapitulate previously described mechanical behavior of cohesive tissues with a continuum model. By contrast, highly motile cells within colonies produce traction stresses that fluctuate in space and time. To predict the traction force dynamics, we introduce an Active Adherent Vertex Model (AAVM) for epithelial monolayers. AAVM predicts that increased cellular motility and reduced intercellular mechanical coupling localize traction stresses in the colony interior, in agreement with our experimental data. Furthermore, the model captures a wide spectrum of localized stress production modes that arise from individual cell activities including cell division, rotation, and polarized migration. This approach provides a robust quantitative framework to study how cell-scale dynamics influence force transmission in epithelial tissues.

Effect of maturational changes in myosin content and morphometry on airway smooth muscle contraction

1991 ◽  
Vol 260 (6) ◽  
pp. L471-L480 ◽  
Author(s):  
T. M. Murphy ◽  
R. W. Mitchell ◽  
A. Halayko ◽  
J. Roach ◽  
L. Roy ◽  
...  
Keyword(s):  
Smooth Muscle ◽  
Muscle Mass ◽  
Morphological Changes ◽  
Rank Order ◽  
Force Generation ◽  
Electron Microscopic ◽  
Cross Sectional ◽  
Tissue Content ◽  
Electron Microscopic Morphometry ◽  
Contractile Forces

We studied the relationship of airway morphometry, the content of myosin heavy-chain and isoform stoichiometry, and the distribution of bronchoconstrictor responses in the airways of maturing swine. Lungs were excised in 2-wk-old farm swine (2ws; n = 13) and 10-wk-old swine (10ws; n = 13), and tracheal smooth muscle strips and bronchial rings from generations 2–5 were fixed for in vitro isometric measurement of force generation. Split samples were placed in formaldehyde solution or glutaraldehyde for light- or electron-microscopic morphometry or frozen for analysis of tissue myosin content. The rank order of force generation elicited by both receptor- and nonreceptor-dependent mechanisms for both 2ws and 10ws was generation 4 greater than 3 greater than or equal to 2. For all matched airway generations, contractile force was 257#x2013;100% greater in 2ws than 10ws. Differences in force generation were not related to morphometric differences in smooth muscle mass content among airways. The relative cross-sectional area of smooth muscle derived by computerized morphometry was 5.5–7% for each airway generation and did not change with age. Electron-microscopic morphometry demonstrated comparable myocyte content within muscle bundles for all airways in both age groups. In generation 4 airways, myocyte size in 2ws (27.3 +/- 0.8 nuclei/2,500 microns2) hypertrophied approximately 15% in 10ws (20.4 +/- 0.6 nuclei/2,500 microns2; P less than 0.01). Tissue content of myosin measured by computerized laser densitometry of gel electrophoresis of homogenates was greater in trachea from 2ws than 10ws (135 +/- 10 vs. 90 +/- 4 micrograms/g tissue; P less than 0.01); homology of 200- and 205-kDa isoforms was confirmed by Western blot against polyclonal myosin antibody and Cleveland digest analysis of each band. Differences in contractile forces between generations in 2ws and 10ws were not correlated to functional myosin isoform content. We demonstrate a maturational downregulation of contractile forces in maturing swine. This response is independent of smooth muscle receptor distribution and is not related to morphological changes in airways muscle mass, cellularity, changes in content of nonmyocyte tissues, or tissue content of functional myosin isoform.

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