H. E. Huxley scite author profile

We have used a small angle scattering system assembled on the high flux multipole wiggler beam line at CHESS (Cornell) to make very accurate spacing measurements of certain meridional and layer-line reflections from contracting muscles. During isometric contraction, the actin 27.3 A reflection increases in spacing from its resting value by approximately 0.3%, and other actin reflections, including the 59 and 51 A off-meridional reflections, show corresponding changes in spacing. When tension is augmented or diminished by applying moderate speed length changes to a contracting muscle, changes in spacing in the range of 0.19-0.24% (when scaled to full isometric tension) can be seen. The larger difference between the resting and isometric spacings suggests either nonlinearity at low tension levels or the presence of a component related to activation itself. Myosin filaments also show similar increases in axial period during slow stretch, in addition to the well known larger change associated with activation. An actin spacing change of 0.25-0.3% can also be measured during a 2 ms time frame immediately after a quick release, showing that the elastic behavior is rapid. These observations of filament extensions totaling 2-3 nm per half-sarcomere may necessitate some significant revision of the interpretation of a number of mechanical experiments in muscle, in which it has usually been assumed that virtually all of the elasticity resides in the cross-bridges.

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Electron microscope studies on the structure of natural and synthetic protein filaments from striated muscle

Huxley

1963

Journal of Molecular Biology

1,389

377

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Structural Changes in the Actin- and Myosin-eontaining Filaments during Contraction

Huxley¹

1973

Cold Spring Harbor Symposia on Quantitative Biology

566

259

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The Double Array of Filaments in Cross-Striated Muscle

Huxley

1957

573

243

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The conditions under which one might expect to see the secondary filaments (if they exist) in longitudinal sections of striated muscle, are discussed. It is shown that these conditions were not satisfied in previously published works for the sections were too thick. When suitably thin sections are examined, the secondary filaments can be seen perfectly easily. It is also possible to see clearly other details of the structure, notably the cross-bridges between primary and secondary filaments, and the tapering of the primary filaments at their ends. The arrangement of the filaments and the changes associated with contraction and with stretch are identical to those already deduced from previous observations and described in terms of the interdigitating filament model in previous papers. There are therefore excellent grounds for believing that this model is correct. The alternative models which have been proposed appear to be incompatible both with the present observations and with much of the other available evidence.

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Regulation of skeletal muscle contraction

Spudich

Huxley

Finch

1972

Journal of Molecular Biology

380

229

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H. E. Huxley

The Mechanism of Muscular Contraction

The low-angle X-ray diagram of vertebrate striated muscle and its behaviour during contraction and rigor

Changes in the Cross-Striations of Muscle during Contraction and Stretch and their Structural Interpretation

X-ray diffraction measurements of the extensibility of actin and myosin filaments in contracting muscle

Electron microscope studies on the structure of natural and synthetic protein filaments from striated muscle

Structural Changes in the Actin- and Myosin-eontaining Filaments during Contraction

The Double Array of Filaments in Cross-Striated Muscle

Regulation of skeletal muscle contraction

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