Myomesin is a molecular spring with adaptable elasticity.

The M-band is a transverse structure in the center of the sarcomere, which is thought to stabilize the thick filament lattice. It was shown recently that the constitutive vertebrate M-band component myomesin can form antiparallel dimers, which might cross-link the neighboring thick filaments. Myomesin consists mainly of immunoglobulin-like (Ig) and fibronectin type III (Fn) domains, while several muscle types express the EH-myomesin splice isoform, generated by the inclusion of the unique EH-segment of about 100 amino acid residues (aa) in the center of the molecule. Here we use atomic force microscopy (AFM), transmission electron microscopy (TEM) and circular dichroism (CD) spectroscopy for the biophysical characterization of myomesin. The AFM identifies the "mechanical fingerprints" of the modules constituting the myomesin molecule. Stretching of homomeric polyproteins, constructed of Ig and Fn domains of human myomesin, produces a typical saw-tooth pattern in the force-extension curve. The domains readily refold after relaxation. In contrast, stretching of a heterogeneous polyprotein, containing several repeats of the My6-EH fragment reveals a long initial plateau corresponding to the sum of EH-segment contour lengths, followed by several My6 unfolding peaks. According to this, the EH-segment is characterized as an entropic chain with a persistence length of about 0.3nm. In TEM pictures, the EH-domain appears as a gap in the molecule, indicating a random coil conformation similar to the PEVK region of titin. CD spectroscopy measurements support this result, demonstrating a mostly non-folded conformation for the EH-segment. We suggest that similarly to titin, myomesin is a molecular spring, whose elasticity is modulated by alternative splicing. The Ig and Fn domains might function as reversible "shock absorbers" by sequential unfolding in the case of extremely high or long sustained stretching forces. These complex visco-elastic properties of myomesin might be crucial for the stability of the sarcomere.

[1]  D. Higgins,et al.  Molecular evolution of immunoglobulin and fibronectin domains in titin and related muscle proteins. , 1999, Gene.

[2]  K Weber,et al.  Molecular structure of the sarcomeric M band: mapping of titin and myosin binding domains in myomesin and the identification of a potential regulatory phosphorylation site in myomesin , 1997, The EMBO journal.

[3]  Siegfried Labeit,et al.  Different molecular mechanics displayed by titin's constitutively and differentially expressed tandem Ig segments. , 2002, Journal of structural biology.

[4]  P. Luther,et al.  Three-dimensional structure of the vertebrate muscle M-region. , 1978, Journal of molecular biology.

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

[6]  M. Gautel,et al.  The structure of the sarcomeric M band: localization of defined domains of myomesin, M-protein, and the 250-kD carboxy-terminal region of titin by immunoelectron microscopy , 1996, The Journal of cell biology.

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

[8]  R. Gomer,et al.  Skelemin, a cytoskeletal M-disc periphery protein, contains motifs of adhesion/recognition and intermediate filament proteins. , 1993, The Journal of biological chemistry.

[9]  Theo Wallimann,et al.  Muscle-type creatine kinase interacts with central domains of the M-band proteins myomesin and M-protein. , 2003, Journal of molecular biology.

[10]  Christian C Witt,et al.  Conditional Expression of Mutant M-line Titins Results in Cardiomyopathy with Altered Sarcomere Structure* , 2003, The Journal of Biological Chemistry.

[11]  A. Pastore,et al.  A survey of the primary structure and the interspecies conservation of I-band titin's elastic elements in vertebrates. , 1998, Journal of structural biology.

[12]  R. Bergman Ultrastructural configuration of sarcomeres in passive and contracted frog sartorius muscle. , 1983, The American journal of anatomy.

[13]  R. J. Podolsky,et al.  The positional stability of thick filaments in activated skeletal muscle depends on sarcomere length: evidence for the role of titin filaments , 1987, The Journal of cell biology.

[14]  Kuan Wang,et al.  Malleable conformation of the elastic PEVK segment of titin: non-co-operative interconversion of polyproline II helix, beta-turn and unordered structures. , 2003, The Biochemical journal.

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

[16]  J. Bechhoefer,et al.  Calibration of atomic‐force microscope tips , 1993 .

[17]  张哉根,et al.  Leu-M , 1991 .

[18]  J C Perriard,et al.  Myofibrillogenesis in the developing chicken heart: assembly of Z-disk, M-line and the thick filaments. , 1999, Journal of cell science.

[19]  H. Huxley,et al.  FILAMENT LENGTHS IN STRIATED MUSCLE , 1963, The Journal of cell biology.

[20]  D. Fürst,et al.  M band proteins myomesin and skelemin are encoded by the same gene: analysis of its organization and expression. , 1999, Genomics.

[21]  J. Hartley,et al.  Cloning multiple copies of a DNA segment. , 1981, Gene.

[22]  E. Ehler,et al.  Dimerisation of myomesin: implications for the structure of the sarcomeric M-band. , 2005, Journal of molecular biology.

[23]  John Trinick,et al.  Titin: properties and family relationships , 2003, Nature Reviews Molecular Cell Biology.

[24]  Siegfried Labeit,et al.  The giant protein titin: a major player in myocardial mechanics, signaling, and disease. , 2004, Circulation research.

[25]  M. Price Skelemins: cytoskeletal proteins located at the periphery of M-discs in mammalian striated muscle , 1987, The Journal of cell biology.

[26]  E. Ehler,et al.  Different domains of the M-band protein myomesin are involved in myosin binding and M-band targeting. , 1999, Molecular biology of the cell.

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

[28]  M. Rief,et al.  The mechanical stability of immunoglobulin and fibronectin III domains in the muscle protein titin measured by atomic force microscopy. , 1998, Biophysical journal.

[29]  U. Vinkemeier,et al.  The globular head domain of titin extends into the center of the sarcomeric M band. cDNA cloning, epitope mapping and immunoelectron microscopy of two titin-associated proteins. , 1993, Journal of cell science.

[30]  Vladimir Benes,et al.  Developmentally Regulated Switching of Titin Size Alters Myofibrillar Stiffness in the Perinatal Heart , 2004, Circulation research.

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

[32]  Siegfried Labeit,et al.  Titin Extensibility In Situ: Entropic Elasticity of Permanently Folded and Permanently Unfolded Molecular Segments , 1998, The Journal of cell biology.

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

[34]  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.

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

[36]  D. Fürst,et al.  Purification and biochemical characterization of myomesin, a myosin-binding and titin-binding protein, from bovine skeletal muscle. , 1995, European journal of biochemistry.

[37]  P. Tompa Intrinsically unstructured proteins. , 2002, Trends in biochemical sciences.

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

[39]  K. Maruyama,et al.  Elastic behavior of connectin filaments during thick filament movement in activated skeletal muscle , 1989, The Journal of cell biology.

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

[41]  R. J. Podolsky,et al.  Thick filament movement and isometric tension in activated skeletal muscle. , 1988, Biophysical journal.

[42]  Mariano Carrion-Vazquez,et al.  The mechanical hierarchies of fibronectin observed with single-molecule AFM. , 2002, Journal of molecular biology.

[43]  D. Auerbach,et al.  Tissue-specific Isoforms of Chicken Myomesin Are Generated by Alternative Splicing* , 1996, The Journal of Biological Chemistry.

[44]  Michelle D. Wang,et al.  Estimating the persistence length of a worm-like chain molecule from force-extension measurements. , 1999, Biophysical journal.

[45]  Dietmar Labeit,et al.  Molecular Mechanics of Cardiac Titin's PEVK and N2B Spring Elements* , 2002, The Journal of Biological Chemistry.

[46]  A. Oberhauser,et al.  Atomic force microscopy captures length phenotypes in single proteins. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[47]  Yiming Wu,et al.  Developmental Control of Titin Isoform Expression and Passive Stiffness in Fetal and Neonatal Myocardium , 2004, Circulation research.

[48]  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.

[49]  H. Granzier,et al.  Molecular dissection of N2B cardiac titin's extensibility. , 1999, Biophysical journal.

[50]  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.

[51]  E. Ehler,et al.  The molecular composition of the sarcomeric M-band correlates with muscle fiber type. , 2004, European journal of cell biology.

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

[53]  J. Evans,et al.  Modeling AFM-induced PEVK extension and the reversible unfolding of Ig/FNIII domains in single and multiple titin molecules. , 2001, Biophysical journal.

[54]  S. Smith,et al.  Complete unfolding of the titin molecule under external force. , 1998, Journal of structural biology.

[55]  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.

[56]  L. Thornell,et al.  Myomesin and M protein: differential expression in embryonic fibers during pectoral muscle development. , 1987, Differentiation; research in biological diversity.

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

[58]  Mathias Gautel,et al.  The elasticity of single titin molecules using a two-bead optical tweezers assay. , 2004, Biophysical journal.

[59]  E. Ehler,et al.  M-band: a safeguard for sarcomere stability? , 2004, Journal of Muscle Research & Cell Motility.

[60]  E. Ehler,et al.  A Novel Marker for Vertebrate Embryonic Heart, the EH-myomesin Isoform* , 2000, The Journal of Biological Chemistry.