Muscle thick filaments are rigid coupled tubules, not flexible ropes.

Understanding the structures of thick filaments and their relation to muscle contraction has been an important problem in muscle biology. The flexural rigidity of natural thick filaments isolated from Caenorhabditis elegans as determined by statistical analysis of their electron microscopic images shows that they are considerably more rigid (persistence length=263 microm) than similarly analyzed synthetic actin filaments (6 microm) or duplex DNA (0.05 microm), which are known to be helical ropes. Indeed, cores of C. elegans thick filaments, having only 11% of the mass per unit length of intact thick filaments, are quite rigid (85 microm) compared with the thick filaments. Cores comprise the backbones of the thick filaments and are composed of tubules containing seven subfilaments cross-linked by non-myosin proteins. Microtubules reconstituted from tubulin and microtubule-associated proteins are nearly as rigid (55 microm) as the cores. We propose a model of coupled tubules as the structural basis for the observed rigidity of natural thick filaments and other linear structures such as microtubules. A similar model was recently presented for microtubules [Felgner et al., 1997]. This coupled tubule model may also explain the differences in flexural rigidity between natural rabbit skeletal muscle thick filaments (27 microm) or synthetic thick filaments reconstituted from myosin and myosin binding protein C (36 microm) and those reconstituted from purified myosin (9 microm). The more flexible myosin structures may be helical ropes like F-actin or DNA, whereas the more rigid muscle or synthetic thick filaments which contain myosin and myosin binding protein C may be constructed of subfilaments coupled into tubules as in C. elegans cores. The observed thick filament rigidity is necessary for the incompressibility and lack of flexure observed with thick filaments in contracting skeletal muscle.

[1]  H. Huxley,et al.  ELECTRON MICROSCOPE STUDIES ON THE STRUCTURE OF NATURAL AND SYNTHETIC PROTEIN FILAMENTS FROM STRIATED MUSCLE. , 1963, Journal of molecular biology.

[2]  J. Lippincott-Schwartz,et al.  Retrograde Transport of Golgi-localized Proteins to the ER , 1998, The Journal of cell biology.

[3]  R. Cook,et al.  Assemblases and coupling proteins in thick filament assembly. , 1997, Cell structure and function.

[4]  J. Dubochet,et al.  Determination of DNA persistence length by cryo-electron microscopy. Separation of the static and dynamic contributions to the apparent persistence length of DNA. , 1995, Journal of molecular biology.

[5]  A C Maggs,et al.  Analysis of microtubule rigidity using hydrodynamic flow and thermal fluctuations. , 1994, The Journal of biological chemistry.

[6]  J. Wray Structure of the backbone in myosin filaments of muscle , 1979, Nature.

[7]  Ueli Aebi,et al.  A Correlative Analysis of Actin Filament Assembly, Structure, and Dynamics , 1997, The Journal of cell biology.

[8]  A. Matus,et al.  Domains of Neuronal Microtubule-associated Proteins and Flexural Rigidity of Microtubules , 1997, The Journal of cell biology.

[9]  Preliminary three-dimensional model for nematode thick filament core. , 1995, Journal of structural biology.

[10]  C. Moos Discussion: Interaction of C-Protein with Myosin and Light Meromyosin , 1973 .

[11]  R. Starr,et al.  Interaction of C-protein with myosin, myosin rod and light meromyosin. , 1975, Journal of molecular biology.

[12]  H. F. Epstein,et al.  Thick filament substructures in Caenorhabditis elegans: evidence for two populations of paramyosin , 1993, The Journal of cell biology.

[13]  A. Huxley,et al.  Structural Changes in Muscle During Contraction: Interference Microscopy of Living Muscle Fibres , 1954, Nature.

[14]  J. Squire,et al.  Packing of α-Helical Coiled-Coil Myosin Rods in Vertebrate Muscle Thick Filaments , 1995 .

[15]  H. F. Epstein,et al.  Paramyosin is necessary for determination of nematode thick filament length in vivo , 1980, Cell.

[16]  H. F. Epstein,et al.  Purified thick filaments from the nematode Caenorhabditis elegans: evidence for multiple proteins associated with core structures , 1988, The Journal of cell biology.

[17]  H E Huxley,et al.  The Mechanism of Muscular Contraction , 1965, Scientific American.

[18]  J. Mizushima-Sugano,et al.  Flexural rigidity of singlet microtubules estimated from statistical analysis of their contour lengths and end-to-end distances. , 1983, Biochimica et biophysica acta.

[19]  R. Williams,et al.  Microtubule-associated proteins and the flexibility of microtubules. , 1995, Biochemistry.

[20]  J. Howard,et al.  Flexural rigidity of microtubules and actin filaments measured from thermal fluctuations in shape , 1993, The Journal of cell biology.

[21]  S. Asakura,et al.  Dark-field light microscopic study of the flexibility of F-actin complexes. , 1980, Journal of molecular biology.

[22]  E. Egelman,et al.  Structure of helical RecA-DNA complexes. Complexes formed in the presence of ATP-gamma-S or ATP. , 1988, Journal of molecular biology.

[23]  G. Offer C-Protein and the Periodicity in the Thick Filaments of Vertebrate Skeletal Muscle , 1973 .

[24]  S. Trachtenberg,et al.  The rigidity of bacterial flagellar filaments and its relation to filament polymorphism. , 1992, Journal of structural biology.

[25]  T. Ebbesen,et al.  Exceptionally high Young's modulus observed for individual carbon nanotubes , 1996, Nature.

[26]  F. Oosawa The flexibility of F-actin. , 1980, Biophysical chemistry.