Journal
NATURE
Volume 528, Issue 7581, Pages 276-+Publisher
NATURE PUBLISHING GROUP
DOI: 10.1038/nature15727
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Funding
- Ente Cassa di Risparmio di Firenze [2010.1402]
- FIRB-Futuro in Ricerca project [RBFR08JAMZ]
- MIUR-PRIN project (Italy) [2010R8JK2X]
- MRC (UK)
- ESRF
- MRC [G0601065] Funding Source: UKRI
- Medical Research Council [G0601065] Funding Source: researchfish
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Contraction of both skeletal muscle and the heart is thought to be controlled by a calcium-dependent structural change in the actin-containing thin filaments, which permits the binding of myosin motors from the neighbouring thick filaments to drive filament sliding(1-3). Here we show by synchrotron small-angle X-ray diffraction of frog (Rana temporaria) single skeletal muscle cells that, although the well-known thin-filament mechanism is sufficient for regulation of muscle shortening against low load, force generation against high load requires a second permissive step linked to a change in the structure of the thick filament. The resting (switched 'OFF') structure of the thick filament is characterized by helical tracks of myosin motors on the filament surface and a short backbone periodicity(2,4,5). This OFF structure is almost completely preserved during low-load shortening, which is driven by a small fraction of constitutively active (switched 'ON') myosin motors outside thick-filament control. At higher load, these motors generate sufficient thick-filament stress to trigger the transition to its long-periodicity ON structure, unlocking the major population of motors required for high-load contraction. This concept of the thick filament as a regulatory mechanosensor provides a novel explanation for the dynamic and energetic properties of skeletal muscle. A similar mechanism probably operates in the heart.
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