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. 2001 Aug;81(2):1093–1100. doi: 10.1016/S0006-3495(01)75766-9

Quantal sarcomere-length changes in relaxed single myofibrils.

F Blyakhman 1, A Tourovskaya 1, G H Pollack 1
PMCID: PMC1301578  PMID: 11463650

Abstract

We carried out experiments on single isolated myofibrils in which thin filaments had been functionally removed, leaving the connecting (titin) filaments as the sole agent taking up the length change. With technical advances that gave sub-nanometer detectability we examined the time course of single sarcomere-length change when the myofibril was ramp-released or ramp-stretched by a motor. The sarcomere-length change was stepwise. Step sizes followed a consistent pattern: the smallest was approximately 2.3 nm, and others were integer multiples of that value. The approximately 2.3-nm step quantum is the smallest consistent biomechanical event ever demonstrated. Although the length change must involve the connecting filament, the size of the quantum is an order of magnitude smaller than anticipated from folding of Ig- or fibronectin-like domains, implying either that folding occurs in sub-domain units or that other mechanisms are involved.

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Selected References

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