2009
DOI: 10.1007/s00424-008-0630-2
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Insights into the kinetics of Ca2+-regulated contraction and relaxation from myofibril studies

Abstract: Muscle contraction results from force-generating interactions between myosin cross-bridges on the thick filament and actin on the thin filament. The force-generating interactions are regulated by Ca(2+) via specialised proteins of the thin filament. It is controversial how the contractile and regulatory systems dynamically interact to determine the time course of muscle contraction and relaxation. Whereas kinetics of Ca(2+)-induced thin-filament regulation is often investigated with isolated proteins, force ki… Show more

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Cited by 68 publications
(81 citation statements)
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References 155 publications
(387 reference statements)
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“…In addition, following Ca 2ϩ activation when steady-state activation was reached, a rapid release-restretch maneuver was imposed to measure k tr , an index that is proportional to the sum of the apparent cross-bridge attachment and detachment rates (30,31). The rates of Ca 2ϩ activation (k Ca ) and k tr were similar in the present study in all experimental groups, consistent with previous reports (29). This finding indicates that the dynamics of Ca 2ϩ binding to cTnI and the subsequent thin filament activation are sufficiently fast to not be rate-limiting for force development.…”
Section: Impact Of Isolated Pka/pkc/rcm On Myofilament Casupporting
confidence: 79%
See 1 more Smart Citation
“…In addition, following Ca 2ϩ activation when steady-state activation was reached, a rapid release-restretch maneuver was imposed to measure k tr , an index that is proportional to the sum of the apparent cross-bridge attachment and detachment rates (30,31). The rates of Ca 2ϩ activation (k Ca ) and k tr were similar in the present study in all experimental groups, consistent with previous reports (29). This finding indicates that the dynamics of Ca 2ϩ binding to cTnI and the subsequent thin filament activation are sufficiently fast to not be rate-limiting for force development.…”
Section: Impact Of Isolated Pka/pkc/rcm On Myofilament Casupporting
confidence: 79%
“…Single Myofibril Activation/Relaxation Kinetics-The single myofibril technique allows for measurement of dynamic Ca 2ϩ activation/relaxation kinetics of force (27)(28)(29). In addition, following Ca 2ϩ activation when steady-state activation was reached, a rapid release-restretch maneuver was imposed to measure k tr , an index that is proportional to the sum of the apparent cross-bridge attachment and detachment rates (30,31).…”
Section: Impact Of Isolated Pka/pkc/rcm On Myofilament Camentioning
confidence: 99%
“…R-t EMG-F, the mainly electrochemical component of R-Delay TOT , likely includes the beginning of Ca 2+ reuptake in the sarcoplasmic reticulum and the transition of cross-bridges from a forcegenerating to a non-force-generating status [17,18,40,41]. The previously mentioned alteration in chloride channels excitability and in SERCA1 and CACNA1S splicing, may have delayed Ca 2+ reuptake in the sarcoplasmic reticulum, [11], and in turn lengthened the mainly electrochemical RDelay TOT component.…”
Section: Delays During Muscle Relaxationmentioning
confidence: 98%
“…Both the passive tension of titin and the active tension of cross-bridges can elevate sarcomere tension during relaxation and thus impair ventricular filling. Incomplete inactivation, either due to an incomplete reduction in [Ca 2+ ] to fully relaxing concentrations or due to an incomplete switching off of the regulatory troponin-tropomyosin system, causes residual active tension and slows relaxation (Iorga et al, 2008;Kruger et al, 2005;Stehle et al, 2009). Here, we use the N2B-knockout mice as a genetic model of diastolic dysfunction to investigate whether increased titin-based stiffness also slows down cardiac myofibrillar relaxation.…”
Section: Introductionmentioning
confidence: 99%