The structural principles of multidomain organization of the giant polypeptide chain of the muscle titin protein: SAXS/WAXS studies during the stretching of oriented titin fibres.

Elasticity of titin is a key parameter that determines the mechanical properties of muscle. These include reversibility, i.e., the muscle's capacity to change its length many-fold and return to its original state, and the transduction of passive tension generated by the stretched muscle. The morphology and elastic properties of oriented fibres of titin molecules were studied using SAXS and WAXS (small- and wide-angle X-ray scattering, respectively) and mechanical techniques. We succeeded in obtaining oriented filaments of purified titin suitable for diffraction measurements. Our X-ray data suggest a model of titin as a nanoscale, morphological, and aperiodical array of rigid Ig- and Fn3-type domains covalently connected by conformationally variable short loops. The line group symmetry of the model can be defined as SM with axial translation tau(infinity). Both tension transduction and high elasticity of titin can be explained in terms of crystalline polymer physics. Titin stretching experiments show that each individual titin macromolecule can adopt a novel two-phase state within the fibre. Conversion between high elasticity and strength can be explained as a phase transition under external tension. In the terms of the concept of orientational melting the origin of the functional heterogeneity along the titin strand becomes interpretable.

[1]  V. Abramov,et al.  Structure of human myeloma IgG3 Kuc. , 1990, European journal of biochemistry.

[2]  J. Trinick,et al.  Direct visualization of extensibility in isolated titin molecules. , 1997, Journal of molecular biology.

[3]  I. Snigireva,et al.  X-ray diffraction study of oriented gels of titin , 2005 .

[4]  Georg E. Schulz,et al.  Principles of Protein Structure , 1979 .

[5]  T. Tameyasu,et al.  Stepwise dynamics of connecting filaments measured in single myofibrillar sarcomeres. , 1998, Biophysical journal.

[6]  W. Linke,et al.  The Giant Protein Titin: Emerging Roles in Physiology and Pathophysiology , 1997 .

[7]  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.

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

[9]  A. A. Vazina Application of synchrotron radiation to small-angle X-ray analysis of biological objects , 1987 .

[10]  H. Higuchi,et al.  An analysis of the dynamic light scattering spectra of wormlike chains: .beta.-connectin from striated muscle , 1993 .

[11]  Peter D. Kwong,et al.  Crystal structure of an HIV-binding recombinant fragment of human CD4 , 1990, Nature.

[12]  J. Trinick,et al.  Extensibility in the titin molecule and its relation to muscle elasticity. , 2000, Advances in experimental medicine and biology.

[13]  H. Granzier,et al.  Protein Kinase A Phosphorylates Titin’s Cardiac-Specific N2B Domain and Reduces Passive Tension in Rat Cardiac Myocytes , 2002, Circulation research.

[14]  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.

[15]  T. Creighton,et al.  Protein Folding , 1992 .

[16]  H. Higuchi,et al.  Behaviour of connectin (titin) and nebulin in skinned muscle fibres released after extreme stretch as revealed by immunoelectron microscopy , 1989, Journal of Muscle Research & Cell Motility.

[17]  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.

[18]  Paul J. Flory,et al.  Theory of Elastic Mechanisms in Fibrous Proteins , 1956 .

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

[20]  D. Parry,et al.  α-Helical coiled coils — a widespread motif in proteins , 1986 .

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

[22]  John Trinick,et al.  Properties of Titin Immunoglobulin and Fibronectin-3 Domains* , 2004, Journal of Biological Chemistry.

[23]  W. Linke,et al.  A spring tale: new facts on titin elasticity. , 1998, Biophysical journal.

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

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

[26]  J. Trinick,et al.  Role of titin in vertebrate striated muscle. , 2002, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[27]  I. Harada,et al.  Infrared Dichroism of an Elastic Portion (1200 kDa Fragment) of Connectin , 1993 .

[28]  V. N. Korneev,et al.  The station for time-resolved investigation in wide and small angles of diffraction , 1998 .

[29]  M. Nilges,et al.  1H and 15N NMR resonance assignments and secondary structure of titin type I domains , 1997, Journal of biomolecular NMR.

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

[31]  Paul Young,et al.  Structural basis for activation of the titin kinase domain during myofibrillogenesis , 1998, Nature.

[32]  A. Pastore,et al.  Immunoglobulin-type domains of titin: same fold, different stability? , 1994, Biochemistry.

[33]  K. Ranatunga Thermal stress and Ca-independent contractile activation in mammalian skeletal muscle fibers at high temperatures. , 1994, Biophysical journal.

[34]  S. Martin,et al.  Titin folding energy and elasticity , 1993, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[35]  H. Granzier,et al.  Titin develops restoring force in rat cardiac myocytes. , 1996, Circulation research.

[36]  H. Sawada,et al.  Molecular size and shape of beta-connectin, an elastic protein of striated muscle. , 1984, Journal of biochemistry.

[37]  A. Pastore,et al.  When a module is also a domain: the rôle of the N terminus in the stability and the dynamics of immunoglobulin domains from titin. , 1997, Journal of molecular biology.

[38]  K Schulten,et al.  Comparison of the early stages of forced unfolding for fibronectin type III modules , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[39]  S. E. Baru,et al.  The use of time-resolved X-ray diffraction and sample techniques for studying the muscle structure during relaxation , 1995 .

[40]  K Weber,et al.  Visualization of the polarity of isolated titin molecules: a single globular head on a long thin rod as the M band anchoring domain? , 1989, The Journal of cell biology.

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

[42]  V. N. Korneev,et al.  Time‐resolved small‐angle x‐ray diffraction from contracting muscle , 1989 .

[43]  M. Nilges,et al.  The three-dimensional structure of a type I module from titin: a prototype of intracellular fibronectin type III domains. , 1998, Structure.

[44]  A. Lesk,et al.  Modularity and homology: modelling of the titin type I modules and their interfaces. , 2001, Journal of molecular biology.

[45]  A. Pastore,et al.  Tertiary structure of an immunoglobulin-like domain from the giant muscle protein titin: a new member of the I set. , 1995, Structure.

[46]  V. N. Korneev,et al.  Studies of the muscle structure during contraction initiated by pairwise stimulation (new results) , 1989 .

[47]  B. Vainshtein,et al.  Diffraction of X-rays by chain molecules , 1966 .

[48]  Emanuele Paci,et al.  Pulling geometry defines the mechanical resistance of a β-sheet protein , 2003, Nature Structural Biology.

[49]  J. Trinick,et al.  Purification and properties of native titin. , 1984, Journal of molecular biology.

[50]  R. Walsh Microtubules and pressure-overload hypertrophy. , 1997, Circulation research.

[51]  M. V. Vol’kenshtein Problems in the theoretical physics of polymers , 1959 .

[52]  Siegfried Labeit,et al.  Cardiac titin: an adjustable multi‐functional spring , 2002, The Journal of physiology.

[53]  A. Pastore,et al.  The elastic I-band region of titin is assembled in a "modular" fashion by weakly interacting Ig-like domains. , 1996, Journal of molecular biology.

[54]  W A Hendrickson,et al.  Structure of a fibronectin type III domain from tenascin phased by MAD analysis of the selenomethionyl protein. , 1992, Science.

[55]  K. Holmes,et al.  X-ray diffraction evidence for α-helical coiled-coils in native muscle , 1963 .

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

[57]  Y. Nonomura,et al.  Connectin, an elastic protein of muscle. Characterization and Function. , 1977, Journal of biochemistry.

[58]  D. Parry Double helix of tropomyosin , 1975, Nature.

[59]  J. Trinick Cytoskeleton: Titin as a scaffold and spring , 1996, Current Biology.

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

[61]  G. Pollack,et al.  Elastic Filaments of the Cell , 2000, Advances in Experimental Medicine and Biology.

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

[63]  H. Granzier,et al.  Nonuniform elasticity of titin in cardiac myocytes: a study using immunoelectron microscopy and cellular mechanics. , 1996, Biophysical journal.

[64]  A. Means Muscle proteins: The clash in titin , 1998, Nature.

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

[66]  K. Maruyama,et al.  Connectin/titin, giant elastic protein of muscle , 1997, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[67]  P J Flory,et al.  Role of Crystallization in Polymers and Proteins. , 1956, Science.

[68]  A. Holmgren,et al.  Crystal structure of chaperone protein PapD reveals an immunoglobulin fold , 1989, Nature.