Residual force enhancement in myofibrils and sarcomeres

Joumaa, Venus; Leonard, Tim; Herzog, Walter

doi:10.1098/rspb.2008.0142

Cited by 128 publications

(191 citation statements)

References 45 publications

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“…In addition, the passive force after deactivation of an actively stretched muscle fibre is higher than the force produced after passive stretch, or after deactivation from an isometric contraction at a corresponding length [18], further suggesting that 'passive force enhancement' is owing to recruitment of a passive element, namely titin [18]. Joumaa et al [34] measured passive force enhancement in myofibrils in which active force production was prevented by removal of troponin C. Like Labeit et al [20], they also observed a Ca 2þ -induced increase in titin-based stiffness, but the increase was too small to account for passive force enhancement. They proposed that passive force enhancement not only requires Ca 2þ influx, but also requires cross-bridge formation or active force production [34].…”

Section: Is There a Role For Titin In Active Muscle?mentioning

confidence: 99%

Is titin a ‘winding filament’? A new twist on muscle contraction

et al. 2011

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Recent studies have demonstrated a role for the elastic protein titin in active muscle, but the mechanisms by which titin plays this role remain to be elucidated. In active muscle, Ca 2þ -binding has been shown to increase titin stiffness, but the observed increase is too small to explain the increased stiffness of parallel elastic elements upon muscle activation. We propose a 'winding filament' mechanism for titin's role in active muscle. First, we hypothesize that Ca 2þ -dependent binding of titin's N2A region to thin filaments increases titin stiffness by preventing low-force straightening of proximal immunoglobulin domains that occurs during passive stretch. This mechanism explains the difference in length dependence of force between skeletal myofibrils and cardiac myocytes. Second, we hypothesize that cross-bridges serve not only as motors that pull thin filaments towards the M-line, but also as rotors that wind titin on the thin filaments, storing elastic potential energy in PEVK during force development and active stretch. Energy stored during force development can be recovered during active shortening. The winding filament hypothesis accounts for force enhancement during stretch and force depression during shortening, and provides testable predictions that will encourage new directions for research on mechanisms of muscle contraction.

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Section: Is There a Role For Titin In Active Muscle?mentioning

confidence: 99%

Is titin a ‘winding filament’? A new twist on muscle contraction

et al. 2011

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“…The force remains elevated after the stretch to reach a steady-state level that is higher than that produced during isometric contractions at corresponding lengths (8,24,38). The mechanisms responsible for this "residual force enhancement" remain elusive and there is substantial disagreement in the literature.Recent studies with isolated myofibrils, preparations in which individual sarcomeres (22,23,36,37,41,43) and half-sarcomeres in series (44, 45) can be evaluated, have shown intriguing results. Whereas a few studies suggest that force enhancement could be linked to sarcomeres and half-SL nonuniformity, as half-sarcomeres change their length continuously during activation and relaxation (36,44,45), some others show that sarcomeres may be stable (22,37), and that the increase in force after stretch are caused by contractile and/or passive structures.…”

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confidence: 99%

“…Whereas a few studies suggest that force enhancement could be linked to sarcomeres and half-SL nonuniformity, as half-sarcomeres change their length continuously during activation and relaxation (36,44,45), some others show that sarcomeres may be stable (22,37), and that the increase in force after stretch are caused by contractile and/or passive structures. Furthermore, studies that attribute the residual force enhancement to sarcomeric structures present experimental data and interpretations that are highly variable.…”

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confidence: 99%

Force produced by isolated sarcomeres and half-sarcomeres after an imposed stretch

Rassier

Pavlov

2012

American Journal of Physiology-Cell Physiology

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Rassier DE, Pavlov I. Force produced by isolated sarcomeres and half-sarcomeres after an imposed stretch. Am J Physiol Cell Physiol 302: C240 -C248, 2012. First published October 12, 2011 doi:10.1152/ajpcell.00208.2011.-When a stretch is imposed to activated muscles, there is a residual force enhancement that persists after the stretch; the force is higher than that produced during an isometric contraction in the corresponding length. The mechanisms behind the force enhancement remain elusive, and there is disagreement if it represents a sarcomeric property, or if it is associated with length nonuniformities among sarcomeres and half-sarcomeres. The purpose of this study was to investigate the effects of stretch on single sarcomeres and myofibrils with predetermined numbers of sarcomeres (n ϭ 2, 3. . . , 8) isolated from the rabbit psoas muscle. Sarcomeres were attached between two precalibrated microneedles for force measurements, and images of the preparations were projected onto a linear photodiode array for measurements of half-sarcomere length (SL). Fully activated sarcomeres were subjected to a stretch (5-10% of initial SL, at a speed of 0.3 m·s Ϫ1 ·SL Ϫ1 ) after which they were maintained isometric for at least 5 s before deactivation. Single sarcomeres showed two patterns: 31 sarcomeres showed a small level of force enhancement after stretch (10.46 Ϯ 0.78%), and 28 sarcomeres did not show force enhancement (Ϫ0.54 Ϯ 0.17%). In these preparations, there was not a strong correlation between the force enhancement and half-sarcomere length nonuniformities. When three or more sarcomeres arranged in series were stretched, force enhancement was always observed, and it increased linearly with the degree of half-sarcomere length nonuniformities. The results show that the residual force enhancement has two mechanisms: 1) stretch-induced changes in sarcomeric structure(s); we suggest that titin is responsible for this component, and 2) stretch-induced nonuniformities of halfsarcomere lengths, which significantly increases the level of force enhancement. myofibrils; myosin; titin; cross-bridges THE NOTION OF SARCOMERE LENGTH (SL) nonuniformity has played a significant role in the study of muscle contraction. It has been directly associated with several experimental observations, including the force "creep" observed at long muscle lengths (11,16), the relation between force and filament overlap (11,17,19), the kinetics of force development and relaxation (9, 43), and the effects of muscle stretch in force production (7,8,13,18,36,37). The latest is particularly important: when a stretch is applied to skeletal muscles during activation, force increases significantly while the energy consumption decreases (1, 30). The force remains elevated after the stretch to reach a steady-state level that is higher than that produced during isometric contractions at corresponding lengths (8,24,38). The mechanisms responsible for this "residual force enhancement" remain elusive and there is substantial disagreement in the literature...

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“…10B) that remains at the end of a long (5-10 s) tetanus was originally observed on isolated whole muscles of the frog (Fenn, 1924;Abbott & Aubert, 1952;Hill & Howarth, 1959) and has later been subjected to detailed studies on isolated single muscle fibres (Edman et al, 1978Sugi, 1972;Edman & Tsuchiya, 1996, Sugi & Tsuchiya, 1988Julian & Morgan, 1979;Rassier & Herzog, 2004a, 2004b, Herzog & Rassier, 2006 and, recently, on isolated cardiac and skeletal muscle myofibrils (Telley et al, 2006;Joumaa et al, 2008;Rassier et al, 2003). The continued interest in this phenomenon is based on the fact that the longlasting force enhancement by stretch does not seem to be readily explainable on the basis of the slidingfilament hypothesis.…”

Section: Residual Force Enhancement After Stretchmentioning

confidence: 99%

Contractile Performance of Striated Muscle

Edman

2010

Advances in Experimental Medicine and Biology

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The single muscle fibre preparation provides an excellent tool for studying the mechanical behaviour of the contractile system at sarcomere level. The present article gives an overview of studies based on intact single fibres from frog and mouse skeletal muscle. The following aspects of muscle function are treated: 1.The length-tension relationship. 2. The biphasic force-velocity relationship. 3. The maximum speed of shortening, its independence of sarcomere length and degree of activation. 4. Force enhancement during stretch, its relation to sarcomere length and myofilament lattice width. 5. Residual force enhancement after stretch.6. Force reduction after loaded shortening. 7. Deactivation by active shortening. 8.Differences in kinetic properties along individual muscle fibres.3

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Residual force enhancement in myofibrils and sarcomeres

Cited by 128 publications

References 45 publications

Is titin a ‘winding filament’? A new twist on muscle contraction

Is titin a ‘winding filament’? A new twist on muscle contraction

Force produced by isolated sarcomeres and half-sarcomeres after an imposed stretch

Contractile Performance of Striated Muscle

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