Structure and periodicities of cross-bridges in relaxation, in rigor, and during contractions initiated by photolysis of caged Ca2+.

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Structure and periodicities of cross-bridges in relaxation, in rigor, and during contractions initiated by photolysis of caged Ca2+.

T D Lenart, J M Murray, C Franzini-Armstrong and Y E Goldman

Pennsylvania Muscle Institute, Department of Physiology, University of Pennsylvania, Philadelphia 19104, USA.

ABSTRACT

Ultra-rapid freezing and electron microscopy were used to directlyobserve structural details of frog muscle fibers in rigor, inrelaxation, and during force development initiated by laserphotolysis of DM-nitrophen (a caged Ca2+). Longitudinal sectionsfrom relaxed fibers show helical tracks of the myosin headson the surface of the thick filaments. Fibers frozen at approximately13, approximately 34, and approximately 220 ms after activationfrom the relaxed state by photorelease of Ca2+ all show surprisinglysimilar cross-bridge dispositions. In sections along the 1,1lattice plane of activated fibers, individual cross-bridge densitieshave a wide range of shapes and angles, perpendicular to thefiber axis or pointing toward or away from the Z line. Thishighly variable distribution is established very early duringdevelopment of contraction. Cross-bridge density across theinterfilament space is more uniform than in rigor, wherein thecross-bridges are more dense near the thin filaments. Opticaldiffraction (OD) patterns and computed power density spectraof the electron micrographs were used to analyze periodicitiesof structures within the overlap regions of the sarcomeres.Most aspects of these patterns are consistent with time resolvedx-ray diffraction data from the corresponding states of intactmuscle, but some features are different, presumably reflectingdifferent origins of contrast between the two methods and possiblealterations in the structure of the electron microscopy samplesduring processing. In relaxed fibers, OD patterns show strongmeridional spots and layer lines up to the sixth order of the43-nm myosin repeat, indicating preservation and resolutionof periodic structures smaller than 10 nm. In rigor, layer linesat 18, 24, and 36 nm indicate cross-bridge attachment alongthe thin filament helix. After activation by photorelease ofCa2+, the 14.3-nm meridional spot is present, but the second-ordermeridional spot (22 nm) disappears. The myosin 43-nm layer linebecomes less intense, and higher orders of 43-nm layer linesdisappear. A 36-nm layer line is apparent by 13 ms and becomesprogressively stronger while moving laterally away from themeridian of the pattern at later times, indicating cross-bridgeslabeling the actin helix at decreasing radius.

This article has been cited by other articles:

R. S. Decker, M. L. Decker, I. Kulikovskaya, S. Nakamura, D. C. Lee, K. Harris, F. J. Klocke, and S. Winegrad
Myosin-Binding Protein C Phosphorylation, Myofibril Structure, and Contractile Function During Low-Flow Ischemia
Circulation, February 22, 2005; 111(7): 906 - 912.
[Abstract] [Full Text] [PDF]

R. T. Tregear, M. C. Reedy, Y. E. Goldman, K. A. Taylor, H. Winkler, C. Franzini-Armstrong, H. Sasaki, C. Lucaveche, and M. K. Reedy
Cross-Bridge Number, Position, and Angle in Target Zones of Cryofixed Isometrically Active Insect Flight Muscle
Biophys. J., May 1, 2004; 86(5): 3009 - 3019.
[Abstract] [Full Text] [PDF]

H. Martin, M. G. Bell, G. C. R. Ellis-Davies, and R. J. Barsotti
Activation Kinetics of Skinned Cardiac Muscle by Laser Photolysis of Nitrophenyl-EGTA
Biophys. J., February 1, 2004; 86(2): 978 - 990.
[Abstract] [Full Text] [PDF]

T. Yamada, Y. Takezawa, H. Iwamoto, S. Suzuki, and K. Wakabayashi
Rigor-Force Producing Cross-Bridges in Skeletal Muscle Fibers Activated by a Substoichiometric Amount of ATP
Biophys. J., September 1, 2003; 85(3): 1741 - 1753.
[Abstract] [Full Text] [PDF]

M. G. Bell, R. E. Dale, U. A. van der Heide, and Y. E. Goldman
Polarized Fluorescence Depletion Reports Orientation Distribution and Rotational Dynamics of Muscle Cross-Bridges
Biophys. J., August 1, 2002; 83(2): 1050 - 1073.
[Abstract] [Full Text] [PDF]

M. Reedy
Visualizing myosin's power stroke in muscle contraction
J. Cell Sci., January 10, 2000; 113(20): 3551 - 3562.
[Abstract] [PDF]

				R. T. Tregear, M. C. Reedy, Y. E. Goldman, K. A. Taylor, H. Winkler, C. Franzini-Armstrong, H. Sasaki, C. Lucaveche, and M. K. Reedy Cross-Bridge Number, Position, and Angle in Target Zones of Cryofixed Isometrically Active Insect Flight Muscle Biophys. J., May 1, 2004; 86(5): 3009 - 3019. [Abstract] [Full Text] [PDF]

				H. Martin, M. G. Bell, G. C. R. Ellis-Davies, and R. J. Barsotti Activation Kinetics of Skinned Cardiac Muscle by Laser Photolysis of Nitrophenyl-EGTA Biophys. J., February 1, 2004; 86(2): 978 - 990. [Abstract] [Full Text] [PDF]

				T. Yamada, Y. Takezawa, H. Iwamoto, S. Suzuki, and K. Wakabayashi Rigor-Force Producing Cross-Bridges in Skeletal Muscle Fibers Activated by a Substoichiometric Amount of ATP Biophys. J., September 1, 2003; 85(3): 1741 - 1753. [Abstract] [Full Text] [PDF]

				M. G. Bell, R. E. Dale, U. A. van der Heide, and Y. E. Goldman Polarized Fluorescence Depletion Reports Orientation Distribution and Rotational Dynamics of Muscle Cross-Bridges Biophys. J., August 1, 2002; 83(2): 1050 - 1073. [Abstract] [Full Text] [PDF]

				M. Reedy Visualizing myosin's power stroke in muscle contraction J. Cell Sci., January 10, 2000; 113(20): 3551 - 3562. [Abstract] [PDF]