Stress-dependent morphogenesis: continuum mechanics and truss systems

A set of equilibrium equations is derived for the stress-controlled shape change of cells due to the remodelling and growth of their internal architecture. The approach involves the decomposition of the deformation gradient into an active and a passive component; the former is allowed to include a growth process, while the latter is assumed to be hyperelastic and mass-preserving. The two components are coupled with a control function that provides the required feedback mechanism. The balance equations for general continua are derived and, using a variational approach, we deduce the equilibrium equations and study the effects of the control function on these equations. The results are applied to a truss system whose function is to simulate the cytoskeletal network constituted by myosin microfilaments and microtubules, which are found experimentally to control shape change in cells. Special attention is paid to the conditions that a thermodynamically consistent formulation should satisfy. The model is used to simulate the multicellular shape changes observed during ventral furrow invagination of the Drosophila melanogaster embryo. The results confirm that ventral furrow invagination can be achieved through stress control alone, without the need for other regulatory or signalling mechanisms. The model also reveals that the yolk plays a distinct role in the process, which is different to its role during invagination with externally imposed strains. In stress control, the incompressibility constraint of the yolk leads, via feedback, to the generation of a pressure in the ventral zone of the epithelium that eventually eases its rise and internalisation.

[1]  Dimitrije Stamenović,et al.  Tensegrity-guided self assembly: from molecules to living cells , 2009 .

[2]  Serdar Göktepe,et al.  A micro-macro approach to rubber-like materials—Part I: the non-affine micro-sphere model of rubber elasticity , 2004 .

[3]  A. Ibrahimbegovic Nonlinear Solid Mechanics , 2009 .

[4]  Larry A. Taber,et al.  Theoretical study of Beloussov’s hyper-restoration hypothesis for mechanical regulation of morphogenesis , 2008, Biomechanics and modeling in mechanobiology.

[5]  Gerhard A. Holzapfel,et al.  Nonlinear Solid Mechanics: A Continuum Approach for Engineering Science , 2000 .

[6]  Paul Steinmann,et al.  On spatial and material settings of hyperelastodynamics , 2002 .

[7]  Ashok Ramasubramanian,et al.  Computational modeling of morphogenesis regulated by mechanical feedback , 2008, Biomechanics and modeling in mechanobiology.

[8]  J. Humphrey Cardiovascular solid mechanics , 2002 .

[9]  Paul Steinmann,et al.  Computational Modelling of Isotropic Multiplicative Growth , 2005 .

[10]  M. Gurtin,et al.  Configurational Forces as Basic Concepts of Continuum Physics , 1999 .

[11]  V. Lubarda Constitutive theories based on the multiplicative decomposition of deformation gradient: Thermoelasticity, elastoplasticity, and biomechanics , 2004 .

[12]  L. Taber Biomechanics of Growth, Remodeling, and Morphogenesis , 1995 .

[13]  M. Bate,et al.  The development of Drosophila melanogaster , 1993 .

[14]  Marcelo Epstein,et al.  Thermomechanics of volumetric growth in uniform bodies , 2000 .

[15]  J. C. Simo,et al.  A finite strain beam formulation. The three-dimensional dynamic problem. Part I , 1985 .

[16]  Antonio DiCarlo,et al.  Growth and balance , 2002 .

[17]  Introduction to the thermomechanics of configurational forces , 2008 .

[18]  L. V. Beloussov,et al.  The Dynamic Architecture of a Developing Organism , 1998, Springer Netherlands.

[19]  Mark Miodownik,et al.  A 3D finite element model of ventral furrow invagination in the Drosophila melanogaster embryo. , 2008, Journal of the mechanical behavior of biomedical materials.

[20]  Gérard A. Maugin,et al.  Material Forces: Concepts and Applications , 1995 .

[21]  Andrew M. Stuart,et al.  A First Course in Continuum Mechanics: Bibliography , 2008 .

[22]  L V Beloussov,et al.  Mechanical stresses in embryonic tissues: patterns, morphogenetic role, and involvement in regulatory feedback. , 1994, International review of cytology.

[23]  F. MacKintosh,et al.  Networks Nonequilibrium Mechanics of Active Cytoskeletal , 2007 .

[24]  H. Narayanan,et al.  Biological remodelling: Stationary energy, configurational change, internal variables and dissipation , 2005, q-bio/0506023.

[25]  L. V. Belousov,et al.  The Dynamic Architecture of a Developing Organism: An Interdisciplinary Approach to the Development of Organisms , 1998 .

[26]  Vlado A. Lubarda,et al.  On the mechanics of solids with a growing mass , 2002 .

[27]  J. D. Eshelby,et al.  The force on an elastic singularity , 1951, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[28]  G. Wayne Brodland,et al.  A cell-based constitutive model for embryonic epithelia and other planar aggregates of biological cells , 2006 .

[29]  Paul Steinmann,et al.  On spatial and material settings of thermo-hyperelastodynamics for open systems , 2003 .

[30]  F. MacKintosh,et al.  Nonequilibrium Mechanics of Active Cytoskeletal Networks , 2007, Science.

[31]  M. Miodownik,et al.  Robust mechanisms of ventral furrow invagination require the combination of cellular shape changes , 2009, Physical biology.

[32]  Mark Miodownik,et al.  A deformation gradient decomposition method for the analysis of the mechanics of morphogenesis. , 2007, Journal of Biomechanics.

[33]  Paul Steinmann,et al.  On Spatial and Material Settings of Thermo-Hyperelastodynamics , 2002 .

[34]  Andreas Menzel,et al.  On the convexity of transversely isotropic chain network models , 2006 .

[35]  M. Boyce,et al.  Constitutive models of rubber elasticity: A review , 2000 .

[36]  L. Taber A model for aortic growth based on fluid shear and fiber stresses. , 1998, Journal of biomechanical engineering.

[37]  D. Ingber Tensegrity: the architectural basis of cellular mechanotransduction. , 1997, Annual review of physiology.

[38]  Arun R. Srinivasa,et al.  On the thermomechanics of materials that have multiple natural configurations Part I: Viscoelasticity and classical plasticity , 2004 .

[39]  George Herrmann,et al.  Mechanics in material space , 2000 .

[40]  Paul Steinmann,et al.  Material forces in open system mechanics , 2004 .

[41]  M. A. Crisfield,et al.  Progressive Delamination Using Interface Elements , 1998 .

[42]  K. Grosh,et al.  Remodeling of biological tissue: Mechanically induced reorientation of a transversely isotropic chain network , 2004, q-bio/0411037.

[43]  P. Alberch,et al.  The mechanical basis of morphogenesis. I. Epithelial folding and invagination. , 1981, Developmental biology.

[44]  A. McCulloch,et al.  Stress-dependent finite growth in soft elastic tissues. , 1994, Journal of biomechanics.

[45]  Davide Carlo Ambrosi,et al.  Stress-Modulated Growth , 2007 .