A novel optical imaging system for investigating sarcomere dynamics in single skeletal muscle fibers

The protein substructure of skeletal muscle fibers forms a diffraction grating with repeating units, termed 'sarcomeres'. A laser scanning system is described that maps the lengths of sarcomeres (SL) and the widths of the first-order diffraction lines (DLW) of permeabilized single fibers in real-time. The apparatus translates a laser beam (λ = 670 nm and w0 = ~75 μm) along the length of a fiber segment through 20 contiguous regions per sweep at 500 sweeps/s. The fiber segments (~1 mm long) were obtained from vastus lateralis muscles of humans by needle biopsy. During both passive stretches and maximum fixed-end activations, the mappings of SL and DLW of the fibers were extracted from the diffraction spectra. Heterogeneity of SLs was evaluated by computing the standard deviation ( σSL) of the 20 SLs measured during a single sweep. Compared with the σSL before a passive stretch, the increase of 5±0.5% in σSL after the passive stretch, indicated differences in passive length-tension relationships along the fiber. In contrast, no change, ~0.5±0.1%, was observed in DLW. Within 10s after the fiber was returned to its initial length, the shape of the SL profile returned close to pre-stretch conditions ( σSL = 1± 0.2%). Following maximum Ca2+ - activation of the fiber, the heterogeneity of the steady state SLs increased greatly (DLW up by ~300% and σSL up by ~100%). The scanning system provided high resolution tracking of sarcomere behavior single muscle fibers. Potential applications are for studies of the mechanisms of muscle fiber injury and injury propagation.

[1]  Y. Goldman,et al.  Measurement of sarcomere shortening in skinned fibers from frog muscle by white light diffraction. , 1987, Biophysical journal.

[2]  D L Morgan,et al.  Intersarcomere dynamics during fixed‐end tetanic contractions of frog muscle fibres. , 1979, The Journal of physiology.

[3]  S. Fujime,et al.  Optical diffraction study of muscle fibers. , 1975, Biochimica et biophysica acta.

[4]  M Kawai,et al.  Optical diffraction studies of muscle fibers. , 1973, Biophysical journal.

[5]  Walter Herzog,et al.  Dynamics of individual sarcomeres during and after stretch in activated single myofibrils , 2003, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[6]  Jachen Denoth,et al.  Half-sarcomere dynamics in myofibrils during activation and relaxation studied by tracking fluorescent markers. , 2006, Biophysical journal.

[7]  K. R. Mills,et al.  Ultrastructural changes after concentric and eccentric contractions of human muscle , 1983, Journal of the Neurological Sciences.

[8]  Richard L Lieber,et al.  Sarcomere strain and heterogeneity correlate with injury to frog skeletal muscle fiber bundles. , 2004, Journal of applied physiology.

[9]  R. Rüdel,et al.  Do laser diffraction studies on striated muscle indicate stepwise sarcomere shortening? , 1979, Nature.

[10]  R. Rüdel,et al.  Efficiency of light diffraction by cross-striated muscle fibers under stretch and during isometric contraction. , 1980, Biophysical journal.

[11]  David Morgan,et al.  Modeling of Lengthening Muscle: The Role of Inter-Sarcomere Dynamics , 1990 .

[12]  J. Faulkner,et al.  Contraction-induced injury to single muscle fibers: velocity of stretch does not influence the force deficit. , 1997, American journal of physiology. Cell physiology.

[13]  Peter Charles Douglas Macpherson Mechanisms involved in the development of contraction-induced injury to single muscle fibres of rats. , 1995 .

[14]  A. Huxley,et al.  Tension development in highly stretched vertebrate muscle fibres , 1966, The Journal of physiology.

[15]  W. Bickel,et al.  Light diffraction studies of single muscle fibers as a function of fiber rotation. , 1984, Biophysical journal.

[16]  A. Hill The mechanics of active muscle , 1953, Proceedings of the Royal Society of London. Series B - Biological Sciences.

[17]  M A Schork,et al.  Contraction-induced injury to single fiber segments from fast and slow muscles of rats by single stretches. , 1996, The American journal of physiology.

[18]  Gaudenz Danuser,et al.  Single muscle fiber contraction is dictated by inter-sarcomere dynamics. , 2002, Journal of theoretical biology.

[19]  D. Morgan New insights into the behavior of muscle during active lengthening. , 1990, Biophysical journal.

[20]  Lucy M. Brown,et al.  Some observations on variations in filament overlap in tetanized muscle fibres and fibres stretched during a tetanus, detected in the electron microscope after rapid fixation , 1991, Journal of Muscle Research & Cell Motility.

[21]  D G Moisescu,et al.  Calcium and strontium concentration changes within skinned muscle preparations following a change in the external bathing solution. , 1978, The Journal of physiology.

[22]  R. Armstrong,et al.  Lesions in the rat soleus muscle following eccentrically biased exercise. , 1988, The American journal of anatomy.

[23]  D. Morgan From sarcomeres to whole muscles. , 1985, The Journal of experimental biology.

[24]  J. Faulkner,et al.  Injury to muscle fibres after single stretches of passive and maximally stimulated muscles in mice. , 1995, The Journal of physiology.

[25]  R L Lieber,et al.  Theory of light diffraction by single skeletal muscle fibers. , 1980, Biophysical journal.

[26]  A. Huxley Muscle structure and theories of contraction. , 1957, Progress in biophysics and biophysical chemistry.

[27]  R. Armstrong,et al.  Mechanical factors in the initiation of eccentric contraction‐induced injury in rat soleus muscle. , 1993, The Journal of physiology.

[28]  J A Faulkner,et al.  Characteristics of lengthening contractions associated with injury to skeletal muscle fibers. , 1986, Journal of applied physiology.

[29]  Walter Herzog,et al.  Considerations on the history dependence of muscle contraction. , 2004, Journal of applied physiology.

[30]  R L Lieber,et al.  Muscle damage is not a function of muscle force but active muscle strain. , 1993, Journal of applied physiology.

[31]  N C Heglund,et al.  Cross-bridge cycling theories cannot explain high-speed lengthening behavior in frog muscle. , 1990, Biophysical journal.