Mechanics and Buckling of Biopolymeric Shells and Cell Nuclei

Slides:



Advertisements
Similar presentations
Volume 105, Issue 8, Pages (October 2013)
Advertisements

Motor Regulation Results in Distal Forces that Bend Partially Disintegrated Chlamydomonas Axonemes into Circular Arcs  V. Mukundan, P. Sartori, V.F. Geyer,
Structural Changes of Cross-Bridges on Transition from Isometric to Shortening State in Frog Skeletal Muscle  Naoto Yagi, Hiroyuki Iwamoto, Katsuaki Inoue 
Goran Žagar, Patrick R. Onck, Erik van der Giessen  Biophysical Journal 
Arikta Biswas, Amal Alex, Bidisha Sinha  Biophysical Journal 
Peter J. Mulligan, Yi-Ju Chen, Rob Phillips, Andrew J. Spakowitz 
Diffusion in a Fluid Membrane with a Flexible Cortical Cytoskeleton
Volume 101, Issue 4, Pages (August 2011)
Mechanical Properties of a Drosophila Larval Chordotonal Organ
John P. Hale, C. Peter Winlove, Peter G. Petrov  Biophysical Journal 
Dynamics of Active Semiflexible Polymers
Volume 113, Issue 12, Pages (December 2017)
Volume 107, Issue 11, Pages (December 2014)
Physical Properties of Escherichia coli Spheroplast Membranes
Susanne Karsch, Deqing Kong, Jörg Großhans, Andreas Janshoff 
William Y.C. Huang, Han-Kuei Chiang, Jay T. Groves  Biophysical Journal 
Joseph M. Johnson, William J. Betz  Biophysical Journal 
MunJu Kim, Katarzyna A. Rejniak  Biophysical Journal 
Mechanics and Buckling of Biopolymeric Shells and Cell Nuclei
Quantifying Cell Adhesion through Impingement of a Controlled Microjet
Volume 111, Issue 2, Pages (July 2016)
Modes of Diffusion of Cholera Toxin Bound to GM1 on Live Cell Membrane by Image Mean Square Displacement Analysis  Pierre D.J. Moens, Michelle A. Digman,
Viscoplasticity Enables Mechanical Remodeling of Matrix by Cells
Jennifer L. Ross, Henry Shuman, Erika L.F. Holzbaur, Yale E. Goldman 
Volume 99, Issue 5, Pages (September 2010)
Christopher B. Stanley, Tatiana Perevozchikova, Valerie Berthelier 
Worms under Pressure: Bulk Mechanical Properties of C
Volume 98, Issue 11, Pages (June 2010)
Emily I. Bartle, Tara M. Urner, Siddharth S. Raju, Alexa L. Mattheyses 
Markita P. Landry, Patrick M. McCall, Zhi Qi, Yann R. Chemla 
Volume 114, Issue 5, Pages (March 2018)
Volume 96, Issue 2, Pages (January 2009)
Collective Cell Migration in Embryogenesis Follows the Laws of Wetting
Cell Traction Forces Direct Fibronectin Matrix Assembly
Taeyoon Kim, Margaret L. Gardel, Ed Munro  Biophysical Journal 
Xiao-Han Li, Elizabeth Rhoades  Biophysical Journal 
Emergent Global Contractile Force in Cardiac Tissues
Fractal Characterization of Chromatin Decompaction in Live Cells
Volume 103, Issue 10, Pages (November 2012)
Volume 107, Issue 7, Pages (October 2014)
Volume 103, Issue 2, Pages (July 2012)
Volume 111, Issue 12, Pages (December 2016)
Actin-Regulator Feedback Interactions during Endocytosis
K. Venkatesan Iyer, S. Pulford, A. Mogilner, G.V. Shivashankar 
Comparative Studies of Microtubule Mechanics with Two Competing Models Suggest Functional Roles of Alternative Tubulin Lateral Interactions  Zhanghan.
Volume 103, Issue 5, Pages (September 2012)
Thermodynamic Characterization of the Unfolding of the Prion Protein
Dynamics of Active Semiflexible Polymers
Volume 111, Issue 4, Pages (August 2016)
Ion-Induced Defect Permeation of Lipid Membranes
Mechanics of Individual Keratin Bundles in Living Cells
Measuring Actin Flow in 3D Cell Protrusions
Volume 108, Issue 10, Pages (May 2015)
Quantification of Fluorophore Copy Number from Intrinsic Fluctuations during Fluorescence Photobleaching  Chitra R. Nayak, Andrew D. Rutenberg  Biophysical.
Interaction of Oxazole Yellow Dyes with DNA Studied with Hybrid Optical Tweezers and Fluorescence Microscopy  C.U. Murade, V. Subramaniam, C. Otto, Martin.
Bending and Puncturing the Influenza Lipid Envelope
Emily I. Bartle, Tara M. Urner, Siddharth S. Raju, Alexa L. Mattheyses 
Christina Ketchum, Heather Miller, Wenxia Song, Arpita Upadhyaya 
John E. Pickard, Klaus Ley  Biophysical Journal 
Volume 113, Issue 3, Pages (August 2017)
Raghvendra Pratap Singh, Ralf Blossey, Fabrizio Cleri 
Volume 100, Issue 6, Pages (March 2011)
Yongli Zhang, Junyi Jiao, Aleksander A. Rebane  Biophysical Journal 
Enrique M. De La Cruz, Jean-Louis Martiel, Laurent Blanchoin 
The Role of Network Architecture in Collagen Mechanics
Ai Kia Yip, Pei Huang, Keng-Hwee Chiam  Biophysical Journal 
Volume 115, Issue 6, Pages (September 2018)
Jennifer L. Ross, Henry Shuman, Erika L.F. Holzbaur, Yale E. Goldman 
Volume 98, Issue 3, Pages (February 2010)
Viscoplasticity Enables Mechanical Remodeling of Matrix by Cells
Presentation transcript:

Mechanics and Buckling of Biopolymeric Shells and Cell Nuclei Edward J. Banigan, Andrew D. Stephens, John F. Marko  Biophysical Journal  Volume 113, Issue 8, Pages 1654-1663 (October 2017) DOI: 10.1016/j.bpj.2017.08.034 Copyright © 2017 Biophysical Society Terms and Conditions

Figure 1 Tension-strain relation for polymeric shells. (A) Shell stretched by tension F exhibits two-regime response, with linear response at small tensions and stiffer linear response to large tensions. Tension-strain curves do not scale simply with N (σ≡N/R2=20 with N=80, red; 100, orange; 250, yellow; 400, light green; 500, dark green; 1000, turquoise; 2000, blue; 3000, purple, 4000, brown; 7000, gray; 15,000, black). Inset: Examples of fitting by Eq. 3. (B) Crossover lengths, ℓ1 and ℓ2, scale linearly with shell radius, R. Colors, shapes, and filling of symbols indicate different σ, k, and kBT, respectively (σ=2, red; 4, orange; 8, dark green; 10, turquoise; 20, blue; 40, purple. k=10, downward pointing triangle; 25, square; 50, diamond; 100, circle; 200, triangle up; 400, triangle left. kBT=10−3, filled; 1, open). (C) Small extension spring constant scales as k1/(σkbond)∼R−1. (D) Large extension spring constant scales as k2/kbond∼R−0.25. Symbols for (C) and (D) are as in (B). Lengths are in units of a, tensions are in simulation force units of f0, spring constants are in units of f0/a, and temperatures are in units of f0a. Measurements are from at least 11 simulations per data point. To see this figure in color, go online. Biophysical Journal 2017 113, 1654-1663DOI: (10.1016/j.bpj.2017.08.034) Copyright © 2017 Biophysical Society Terms and Conditions

Figure 2 Buckling of stretched polymeric shells. (A) Two views of stretched shell with multiple buckles perpendicular to tension axis extending longitudinally across the shell. (B) Transverse strain, ΔL⊥/L, versus tension, F, drops sharply at the buckling transition. (C) Tension-strain relation exhibits a signature of the buckling transition, with a jump in strain that increases with increasing temperature (kBT=0 (no Langevin noise, see Materials and Methods), red; 10−3, orange; 10−2, green; 10−1, blue; 1, purple). Black squares show hysteretic behavior of tension-strain relation for shells evolved at kBT=10−3 after a transient of kBT=1. (D) Normalized Fourier modes, Fn(F) (Eqs. 8 and 9), indicate buckling by increases in modes with n≥2 at tensions corresponding to the jump in the tension-strain curve (n=0, red; 2, orange; 3, yellow; 4, light green; 5, dark green; 6, turquoise; 7, blue; 8, purple). To see this figure in color, go online. Biophysical Journal 2017 113, 1654-1663DOI: (10.1016/j.bpj.2017.08.034) Copyright © 2017 Biophysical Society Terms and Conditions

Figure 3 Stretched laminas, but not the nuclei containing chromatin, exhibit axial buckles. (A) Representative images of an unstretched (left) and stretched (right) lamina, obtained by treating HeLa nuclei with MNase, which digests chromatin. Stretched image shows longitudinal buckles. (B) Representative images of nuclei with intact chromatin interior, which do not exhibit buckling when stretched (right; compare to left, unstretched). Scale bars represent 5μm. Fluorescence signal is GFP-lamin A. (C) Line scans along the central axis perpendicular to the tension axis showing the GFP-lamin A signal for an MNase-treated nucleus when unstretched (solid line) and stretched (dashed line), corresponding to the images in (A). GFP-lamin A intensity is plotted in arbitrary units. (D) Line scans along the central axis perpendicular to the tension axis showing the GFP-lamin A signal for an untreated nucleus when unstretched (solid line) and stretched (dashed line), corresponding to the images in (B). (E) Table listing average number of excess peaks (between boundary peaks) per line scan. Seven nuclei were imaged for each case. Error is given by SE. Biophysical Journal 2017 113, 1654-1663DOI: (10.1016/j.bpj.2017.08.034) Copyright © 2017 Biophysical Society Terms and Conditions

Figure 4 Shells filled with a tethered cross-linked polymer, modeling a cell nucleus, do not axially buckle. (A) Force-extension curves for MEF-V−/− nuclei in experiments in which nuclei were treated with MNase (red) and without (purple) MNase treatment. Inset: Bar graph showing effective spring constants for MEF-V−/− nuclei in short and long extension regimes with (red) and without (purple) MNase treatment. Measurements were performed for 18 untreated and five MNase-treated nuclei. Error bars are mean ± SE. Statistical significance of p<0.05 was established by t-test. (B) Tension-strain relation shows that the tethered cross-linked polymer interior strengthens initial force response (purple, as compared to empty shell, red). Simulation units are a=0.7μm and f0=5.9pN. (C) Although there are localized buckles in the stretched shell with a tethered polymer interior, buckles do not span the entire structure. (D) Normalized Fourier modes show weaker signature of buckling, compared to those of Fig. 2 D (n=0, red; 2, orange; 3, yellow; 4, light green; 5, dark green; 6, turquoise; 7, blue; 8, purple). Inset: Transverse strain for shells enclosing a tethered polymer (purple) and empty shells (red). z=4 (〈z〉≈4.5) in (B)–(D). To see this figure in color, go online. Biophysical Journal 2017 113, 1654-1663DOI: (10.1016/j.bpj.2017.08.034) Copyright © 2017 Biophysical Society Terms and Conditions