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Query: EC:1.13.12.5 (
aequorin
)
1,451
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Data from intact and skinned muscle fibers support the hypothesis that cross-bridge interaction modifies
TnC
structure and calcium activation. Barnacle single muscle fibers microinjected with the calcium bioluminescent photoprotein,
aequorin
, show extra light (calcium) when shortened during the declining phase of the calcium transient. The extra calcium is increased by increases in muscle force, and its decline is delayed at higher forces. This extra calcium occurs probably because calcium binding to the activating sites is increased by cross-bridge interaction. In rabbit muscle,
TnC
structure is modified by cross-bridge interaction, since in skinned rabbit psoas muscle fibers
TnC
extraction is slower at shorter sarcomere lengths, where cross-bridge attachment is increased. Thus the rigor bridges formed in the extraction solution strengthen the attachment of
TnC
to the thin filament. Reintroduction of
TnC
, labeled with fluorescent probes near the Ca specific binding sites (Danzylaziridine-DANZ) and Ca-Mg sites (Rhodamine), into the partially
TnC
extracted fibers allows us to assess the structural changes (total fluorescence for the DANZ probes, linear dichroism for the RHOD probe) in response to calcium binding and cross-bridge attachment. At sarcomere lengths beyond overlap, calcium binding increases the DANZ-
TnC
fluorescence and disorders the RHOD-
TnC
label. At full overlap of filaments, rigor cross-bridges also increase the DANZ-
TnC
fluorescence and RHOD-
TnC
disorder. The addition of calcium in rigor increases the DANZ-
TnC
fluorescence little but causes additional RHOD-
TnC
disorder, although both fluorescence and disorder are increased further in the presence of calcium plus MgATP. In fibers containing DANZ-
TnC
, decreasing MgATP in the absence of calcium increases both the force and the fluorescence as rigor cross-bridges activate the muscle. In the presence of calcium, an increase in MgATP to 0.75 microM produces a small fluorescent enhancement, but an increase in MgATP to 10 microM and to 3 mM produces a substantial enhancement. The data imply that calcium activates the thin filament, but that the filament is activated further by rigor cross-bridges. Active cross-bridges activate the thin filament still further. Thus, cross-bridges modify
TnC
structure and calcium activation, with active cross-bridges being more effective than rigor cross-bridges.
...
PMID:Muscle cross-bridge attachment: effects on calcium binding and calcium activation. 326 97
The timing of events associated with the contraction and relaxation of the force cycle is described in isolated single arthropod muscle fibers using the fluorescently labelled derivatives of the Ca2+ binding sub-unit of troponin
TnC
. The kinetics of the subtracted fluorescence (490-410 nm) response from injected TnCDANZ, labelled at the Ca2+ specific sites, shows a rapid rise which is some 90% complete at 50% force consistent with rapid Ca2+ binding to this sub-unit. Subsequently the TnCDANZ fluorescence decays 2x more slowly, at 12 degrees C, than force consistent with a slower release of this bound Ca2+. In fibers injected with both
aequorin
and TnCDANZ, the
aequorin
kinetics are essentially unaltered compared to control fibers in the presence of 10-100 microM TnCDANZ. The peak of the
aequorin
response occurs some 150-170 msec in front of the TnCDANZ peak and the T 1/2 for light decay is faster than either force or TnCDANZ decay, but there is a 'tail' to the
aequorin
light response (elevated free Ca2+) well into the relaxation phase, seen both in cannulated and intact muscle fibers. The kinetics of the fluorescence of TnCIAANS, labelled of the Ca2+-Mg2+ sites, shows a slow decrease (T 1/2 1.8 sec) and subsequent increase (T 1/2 2.5 sec) in fluorescence consistent with a slow loading and unloading of these sites with Ca2+ during a tetanus. Time resolved X-ray diffraction from intact muscle fibers indicate that forces of up to 600 kN/m2 can be developed at sarcomere lengths of 8-10 micron. Force shows a marked sarcomere dependency while the
aequorin
response is relatively insensitive. At these high forces, there is a marked change in intensity of the first actin layer line (A2 at 38 nm), consistent with S1 (cross-bridge) attachment, which has a T 1/2 for rise of 125-150 msec.
...
PMID:Transient kinetics and time-resolved X-ray diffraction studies in isolated single muscle fibres. 340 11
The Ca2+-sensitive photoprotein
aequorin
and the Ca2+-dependent fluorescent indicators quin 2 and TnCDANZ have been used to investigate contractile processes in single crustacean muscle fibres. The investigations with quin 2 indicate that the free Ca2+ rises to a maximum value before peak force as with
aequorin
light (approximately 200 msec delay at 12 degrees C) and subsequently decays more slowly, unlike the majority of the
aequorin
signal, although an
aequorin
'tail' signal remains. The resting quin 2 fluorescence from the cell suggests an upper limit of 348 nM for the resting calcium concentration. Experiments with TnCDANZ indicate that this fluorescence response rises rapidly but then the rate of rise slows to reach a maximum value at a time when peak force is achieved and then the fluorescence signal decays more slowly than force. The latter result implies that Ca2+ is attached to the Ca2+-specific sites of
TnC
when externally recorded force is small.
...
PMID:Kinetic investigations in single muscle fibres using luminescent and fluorescent Ca2+ probes. 389 26
In vertebrate striated muscle, calcium binding to troponin initiates contraction, a strong interaction of actin and myosin. In isolated proteins and skinned fibers, the strong interaction of myosin with actin also affects troponin. Fluorescent labels attached to troponin C show structural changes in the
TnC
environment with cross-bridge attachment and also with calcium binding. Evidence that this effect of crossbridges also occurs in intact striated muscle comes from studies in partially activated cardiac or skeletal muscle by others and in barnacle muscle by us. Length changes which detach myosin cross-bridges produce a brief burst of extra calcium that can be detected by
aequorin
in activated, voltage clamped single barnacle muscle fibers. That this calcium is coming from calcium bound to the activating site (troponin-C) is supported by several pieces of evidence. Studies on the dependence of the extra calcium on force and the time of the length change are consistent with the amplitude of the extra calcium being proportional to the bound calcium (CaTnC) and with increased cross-bridge attachment and force increasing calcium binding to troponin-C by up to a factor of 10. Importantly, stretch of active muscle (which first detaches cross-bridges and then enhances steady force) gives a biphasic response: first extra calcium (presumably due to cross-bridge detachment) and then, decreased calcium (presumably due to enhanced calcium binding to
TnC
). The enhanced calcium binding we see with elevated force (via strained cross-bridges) implies that calcium binding to
TnC
is enhanced not only be cross-bridge attachment but also by crossbridge (or thin filament) strain. This effect of cross-bridge attachment/force on calcium binding is consistent with a dual mechanism of calcium activation of contraction. First, calcium binds to troponin in the thin filament activating strong myosin binding to the thin filament. Then, strong myosin binding in turn provides additional activation either by increasing calcium binding or by changing the thin filament structure directly allowing additional cross-bridge attachment.
...
PMID:Cross-bridges affect both TnC structure and calcium affinity in muscle fibers. 810 32
