Abstract
Contraction of striated muscle is tightly regulated by the release and sequestration of calcium within myocytes. At the molecular level, calcium modulates myosin's access to the thin filament. Once bound, myosin is hypothesized to potentiate the binding of further myosins. Here, we directly image single molecules of myosin binding to and activating thin filaments. Using this approach, the cooperative binding of myosin along thin filaments has been quantified. We have found that two myosin heads are required to laterally activate a regulatory unit of thin filament. The regulatory unit is found to be capable of accommodating 11 additional myosins. Three thin filament activation states possessing differential myosin binding capacities are also visible. To describe this system, we have formulated a simple chemical kinetic model of cooperative activation that holds across a wide range of solution conditions. The stochastic nature of activation is strongly highlighted by data obtained in sub-optimal activation conditions where the generation of activation waves and their catastrophic collapse can be observed. This suggests that the thin filament has the potential to be turned fully on or off in a binary fashion.
Highlights
How calcium regulates thin filament activation is uncertain
A high signal-to-noise ratio was achieved using an obliquely angled fluorescent light sheet (OAF) [17], termed HiLo or variable angle TIRF [21, 22], which illuminated the region in the proximity of the tightropes (Fig. 1c)
The mechanism by which muscle contraction is controlled provides a paradigm for understanding the processes of cooperativity and biological systems more generally
Summary
How calcium regulates thin filament activation is uncertain. Results: Single molecule imaging is used to report on thin filament activation across relevant solution conditions. Because tropomyosin forms a head-to-tail continuous filament along actin, a clear structural mechanism for communication of myosin binding along the thin filament is apparent [3] This complex set of interactions permits muscle to be rapidly cycled between active and inactive states in a calcium-dependent manner [1, 4, 5], crucial for the function of vital organs such as the heart. Calcium only partially activates the thin filament, but in the presence of myosin an activation patch permitting ϳ11 myosins to bind locally is formed These regions of activation can grow, split, diffuse, and catastrophically collapse providing a clear view of how the thin filament activates and deactivates. All of these observations have been put together into a simple steady-state model of activation, providing a crucial translation from the stochastic single molecule picture of activation to that of ensemble studies
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