Cardiac titin: molecular basis of elasticity and cellular contribution to elastic and viscous stiffness components in myocardium

Myocardium resists the inflow of blood during diastole through stretch-dependent generation of passive tension. Earlier we proposed that this tension is mainly due to collagen stiffness at degrees of stretch corresponding to sarcomere lengths (SLS) ≥2.2 μm, but at shorter lengths, is principally determined by the giant sarcomere protein titin. Myocardial passive force consists of stretch-velocity-sensitive (viscous/viscoelastic) and velocity-insensitive (elastic) components; these force components are seen also in isolated cardiac myofibrils or skinned cells devoid of collagen. Here we examine the cellular/myofibrillar origins of passive force and describe the contribution of titin, or interactions involving titin, to individual passive-force components. We construct force–extension relationships for the four distinct elastic regions of cardiac titin, using results of in situ titin segment-extension studies and force measurements on isolated cardiac myofibrils. Then, we compare these relationships with those calculated for each region with the wormlike-chain (WLC) model of entropic polymer elasticity. Parameters used in the WLC calculations were determined experimentally by single-molecule atomic force-microscopy measurements on engineered titin domains. The WLC modelling faithfully predicts the steady-state-force vs. extension behavior of all cardiac-titin segments over much of the physiological SL range. Thus, the elastic-force component of cardiac myofibrils can be described in terms of the entropic-spring properties of titin segments. In contrast, entropic elasticity cannot account for the passive-force decay of cardiac myofibrils following quick stretch (stress relaxation). Instead, slower (viscoelastic) components of stress relaxation could be simulated by using a Monte-Carlo approach, in which unfolding of a few immunoglobulin domains per titin molecule explains the force decay. Fast components of stress relaxation (viscous drag) result mainly from interaction between actin and titin filaments; actin extraction of cardiac sarcomeres by gelsolin immediately suppressed the quickly decaying force transients. The combined results reveal the sources of velocity sensitive and insensitive force components of cardiomyofibrils stretched in diastole.

[1]  T. Irving,et al.  Myofilament Calcium Sensitivity in Skinned Rat Cardiac Trabeculae: Role of Interfilament Spacing , 2002, Circulation research.

[2]  H. Granzier,et al.  Changes in titin and collagen underlie diastolic stiffness diversity of cardiac muscle. , 2000, Journal of molecular and cellular cardiology.

[3]  Wolfgang A. Linke,et al.  Reverse engineering of the giant muscle protein titin , 2002, Nature.

[4]  W. Linke,et al.  Nature of PEVK-titin elasticity in skeletal muscle. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[5]  Piotr E. Marszalek,et al.  Stretching single molecules into novel conformations using the atomic force microscope , 2000, Nature Structural Biology.

[6]  M. Greaser,et al.  Identification of new repeating motifs in titin , 2001, Proteins.

[7]  K. Ranatunga,et al.  Tension relaxation after stretch in resting mammalian muscle fibers: stretch activation at physiological temperatures. , 1996, Biophysical journal.

[8]  D. K. Hill,et al.  Tension due to interaction between the sliding filaments in resting striated muscle. the effect of stimulation , 1968, The Journal of physiology.

[9]  S. Labeit,et al.  Towards a molecular understanding of titin. , 1992, The EMBO journal.

[10]  F. John,et al.  Stretching DNA , 2022 .

[11]  M. Bartoo,et al.  Limits of titin extension in single cardiac myofibrils , 1996, Journal of Muscle Research & Cell Motility.

[12]  F. Julian,et al.  Absence of a plateau in length–tension relationship of rabbit papillary muscle when internal shortening is prevented , 1976, Nature.

[13]  Siegfried Labeit,et al.  Titins: Giant Proteins in Charge of Muscle Ultrastructure and Elasticity , 1995, Science.

[14]  W. Linke,et al.  Characterizing titin's I-band Ig domain region as an entropic spring. , 1998, Journal of cell science.

[15]  S. Smith,et al.  Folding-unfolding transitions in single titin molecules characterized with laser tweezers. , 1997, Science.

[16]  J. M. Fernández,et al.  Unfolding of titin domains explains the viscoelastic behavior of skeletal myofibrils. , 2001, Biophysical journal.

[17]  H. Higuchi,et al.  Characterization of beta-connectin (titin 2) from striated muscle by dynamic light scattering. , 1993, Biophysical journal.

[18]  T. Suzuki,et al.  Extensible and less-extensible domains of connectin filaments in stretched vertebrate skeletal muscle sarcomeres as detected by immunofluorescence and immunoelectron microscopy using monoclonal antibodies. , 1988, Journal of biochemistry.

[19]  R. M. Simmons,et al.  Elasticity and unfolding of single molecules of the giant muscle protein titin , 1997, Nature.

[20]  M. Bartoo,et al.  Basis of passive tension and stiffness in isolated rabbit myofibrils. , 1997, The American journal of physiology.

[21]  H. T. ter Keurs,et al.  Ca(2+)-dependence of diastolic properties of cardiac sarcomeres: involvement of titin. , 1998, Progress in biophysics and molecular biology.

[22]  G H Pollack,et al.  Passive and active tension in single cardiac myofibrils. , 1994, Biophysical journal.

[23]  W. Gaasch,et al.  Giant molecule titin and myocardial stiffness. , 2002, Circulation.

[24]  K. Wang,et al.  Viscoelasticity of the sarcomere matrix of skeletal muscles. The titin-myosin composite filament is a dual-stage molecular spring. , 1993, Biophysical journal.

[25]  H. Erickson,et al.  Reversible unfolding of fibronectin type III and immunoglobulin domains provides the structural basis for stretch and elasticity of titin and fibronectin. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[26]  A. Pastore,et al.  Immunoglobulin-like modules from titin I-band: extensible components of muscle elasticity. , 1996, Structure.

[27]  M. Noble,et al.  The Diastolic Viscous Properties of Cat Papillary Muscle , 1977, Circulation research.

[28]  W. Linke,et al.  Actin-titin interaction in cardiac myofibrils: probing a physiological role. , 1997, Biophysical journal.

[29]  H Li,et al.  Atomic force microscopy reveals the mechanical design of a modular protein. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[30]  J. Trinick,et al.  Titin: a molecular control freak. , 1999, Trends in cell biology.

[31]  W. Linke,et al.  Interaction Between PEVK-Titin and Actin Filaments: Origin of a Viscous Force Component in Cardiac Myofibrils , 2001, Circulation research.

[32]  W. Linke,et al.  Towards a molecular understanding of the elasticity of titin. , 1996, Journal of molecular biology.

[33]  Andres F. Oberhauser,et al.  The molecular elasticity of the extracellular matrix protein tenascin , 1998, Nature.

[34]  T Centner,et al.  Series of exon-skipping events in the elastic spring region of titin as the structural basis for myofibrillar elastic diversity. , 2000, Circulation research.

[35]  H. Erickson,et al.  Stretching Single Protein Molecules: Titin Is a Weird Spring , 1997, Science.

[36]  Roger J Hajjar,et al.  Titin Isoform Switch in Ischemic Human Heart Disease , 2002, Circulation.

[37]  J. Trinick,et al.  Titin and the sarcomere symmetry paradox. , 2001, Journal of molecular biology.

[38]  J. Clarke,et al.  Mechanical and chemical unfolding of a single protein: a comparison. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[39]  J. Trinick,et al.  Flexibility and extensibility in the titin molecule: analysis of electron microscope data. , 2001, Journal of molecular biology.

[40]  A. Oberhauser,et al.  Mechanical design of proteins studied by single-molecule force spectroscopy and protein engineering. , 2000, Progress in biophysics and molecular biology.

[41]  D. Allen,et al.  The cellular basis of the length-tension relation in cardiac muscle. , 1985, Journal of molecular and cellular cardiology.

[42]  K. Ranatunga Sarcomeric visco-elasticity of chemically skinned skeletal muscle fibres of the rabbit at rest , 2004, Journal of Muscle Research & Cell Motility.

[43]  T Centner,et al.  Mechanically driven contour-length adjustment in rat cardiac titin's unique N2B sequence: titin is an adjustable spring. , 1999, Circulation research.

[44]  U. Proske,et al.  Do cross-bridges contribute to the tension during stretch of passive muscle? , 1999, Journal of Muscle Research & Cell Motility.

[45]  W. Linke,et al.  Sarcomere length-tension relationship of rat cardiac myocytes at lengths greater than optimum. , 2000, Journal of molecular and cellular cardiology.

[46]  G. Gutierrez-Cruz,et al.  Modular Motif, Structural Folds and Affinity Profiles of the PEVK Segment of Human Fetal Skeletal Muscle Titin* , 2001, The Journal of Biological Chemistry.

[47]  A. Pastore,et al.  The folding and stability of titin immunoglobulin-like modules, with implications for the mechanism of elasticity. , 1995, Biophysical journal.

[48]  M. Gautel,et al.  Assembly of the cardiac I-band region of titin/connectin: expression of the cardiac-specific regions and their structural relation to the elastic segments , 1996, Journal of Muscle Research & Cell Motility.

[49]  M. Gautel,et al.  A molecular map of titin/connectin elasticity reveals two different mechanisms acting in series , 1996, FEBS letters.

[50]  M. Lakie,et al.  A cross‐bridge mechanism can explain the thixotropic short‐range elastic component of relaxed frog skeletal muscle , 1998, The Journal of physiology.

[51]  Dietmar Labeit,et al.  The Complete Gene Sequence of Titin, Expression of an Unusual ≈700-kDa Titin Isoform, and Its Interaction With Obscurin Identify a Novel Z-Line to I-Band Linking System , 2001 .

[52]  Wolfgang A. Linke,et al.  I-Band Titin in Cardiac Muscle Is a Three-Element Molecular Spring and Is Critical for Maintaining Thin Filament Structure , 1999, The Journal of cell biology.

[53]  F. Goubel,et al.  Passive stiffness changes in soleus muscles from desmin knockout mice are not due to titin modifications , 2002, Pflügers Archiv.

[54]  Mathias Gautel,et al.  PEVK domain of titin: an entropic spring with actin-binding properties. , 2002, Journal of structural biology.

[55]  H. T. ter Keurs,et al.  Comparison between the Sarcomere Length‐Force Relations of Intact and Skinned Trabeculae from Rat Right Ventricle: Influence of Calcium Concentrations on These Relations , 1986, Circulation research.

[56]  L. E. Ford,et al.  Internal viscoelastic loading in cat papillary muscle. , 1982, Biophysical journal.

[57]  K. Maruyama,et al.  Connectin, an elastic protein of muscle. A connectin-like protein from the plasmodium Physarum polycephalum. , 1980, Journal of biochemistry.

[58]  P. D. de Tombe,et al.  An internal viscous element limits unloaded velocity of sarcomere shortening in rat myocardium. , 1992 .

[59]  K. Wang Titin/connectin and nebulin: giant protein rulers of muscle structure and function. , 1996, Advances in biophysics.

[60]  D. Urry Protein elasticity based on conformations of sequential polypeptides: The biological elastic fiber , 1984 .

[61]  Matthias Rief,et al.  Elastically Coupled Two-Level Systems as a Model for Biopolymer Extensibility , 1998 .

[62]  K W Ranatunga,et al.  Temperature‐dependent changes in the viscoelasticity of intact resting mammalian (rat) fast‐ and slow‐twitch muscle fibres , 1998, The Journal of physiology.

[63]  K. Weber,et al.  The organization of titin filaments in the half-sarcomere revealed by monoclonal antibodies in immunoelectron microscopy: a map of ten nonrepetitive epitopes starting at the Z line extends close to the M line , 1988, The Journal of cell biology.

[64]  M. Rief,et al.  Reversible unfolding of individual titin immunoglobulin domains by AFM. , 1997, Science.

[65]  A. Oberhauser,et al.  Multiple conformations of PEVK proteins detected by single-molecule techniques , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[66]  K. Weber,et al.  Extracellular matrix remodeling in heart failure: a role for de novo angiotensin II generation. , 1997, Circulation.

[67]  G. Pollack,et al.  Interaction between titin and thin filaments in intact cardiac muscle , 1997, Journal of Muscle Research & Cell Motility.

[68]  W. Linke,et al.  Kettin, a major source of myofibrillar stiffness in Drosophila indirect flight muscle , 2001, The Journal of cell biology.

[69]  T Centner,et al.  The complete gene sequence of titin, expression of an unusual approximately 700-kDa titin isoform, and its interaction with obscurin identify a novel Z-line to I-band linking system. , 2001, Circulation research.

[70]  W. Linke,et al.  Stretching molecular springs: elasticity of titin filaments in vertebrate striated muscle. , 2000, Histology and histopathology.

[71]  E. Siggia,et al.  Entropic elasticity of lambda-phage DNA. , 1994, Science.