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Query: UNIPROT:P21817 (
RyR1
)
1,154
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Ca2+ ions play a pivotal role in a wide array of cellular processes ranging from fertilization to cell death. In skeletal muscle, a mechanical interaction between plasma membrane dihydropyridine receptors (DHPRs, L-type Ca2+ channels) and Ca2+ release channels (ryanodine receptors, RyR1s) of the sarcoplasmic reticulum orchestrates a complex, bi-directional Ca2+ signaling process that converts electrical impulses in the sarcolemma into myoplasmic Ca2+ transients during excitation-contraction coupling. Mutations in the genes that encode the two proteins that coordinate this electrochemical conversion process (the
DHPR
and
RyR1
) result in a variety of skeletal muscle disorders including malignant hyperthermia (MH), central core disease (CCD), multiminicore disease, nemaline rod myopathy, and hypokalemic periodic paralysis. Although
RyR1
and
DHPR
disease mutations are thought to alter excitability and Ca2+ homeostasis in skeletal muscle, only recently has research begun to probe the molecular mechanisms by which these genetic defects lead to distinct clinical and histopathological manifestations. This review focuses on recent advances in determining the impact of MH and CCD mutations in
RyR1
on muscle Ca2+ signaling and how these effects contribute to disease-specific aspects of these disorders.
...
PMID:Dynamic alterations in myoplasmic Ca2+ in malignant hyperthermia and central core disease. 1533 73
The aim of the present study was to explore interactions between surface-membrane
DHPR
(dihydropyridine receptor) Ca2+ channels and RyR (ryanodine receptor) Ca2+ channels in skeletal-muscle sarcoplasmic reticulum. The C region (725Phe-Pro742) of the linker between the 2nd and 3rd repeats (II-III loop) of the a1 subunit of skeletal DHPRs is essential for skeletal excitation-contraction coupling, which requires a physical interaction between the
DHPR
and RyR and is independent of external Ca2+. Little is known about the regulatory processes that might take place when the two Ca2+ channels interact. Indeed, interactions between C fragments of the
DHPR
(C peptides) and RyR have different reported effects on Ca2+ release from the sarcoplasmic reticulum and on RyR channels in lipid bilayers. To gain insight into functional interactions between the proteins and to explore different reported effects, we examined the actions of C peptides on
RyR1
channels in lipid bilayers with three key RyR regulators, Ca2+, Mg2+ and ATP. We identified four discrete actions: two novel, low-affinity (>10 microM), rapidly reversible effects (fast inhibition and decreased sensitivity to Mg2+ inhibition) and two slowly reversible effects (high-affinity activation and a slow-onset, low-affinity inhibition). Fast inhibition and high-affinity activation were decreased by ATP. Therefore peptide activation in the presence of ATP and Mg2+, used with Ca2+ release assays, depends on a mechanism different from that seen when Ca2+ is the sole agonist. The relief of Mg2+ inhibition was particularly important since RyR activation during excitation-contraction coupling depends on a similar decrease in Mg2+ inhibition.
...
PMID:Regulation of skeletal ryanodine receptors by dihydropyridine receptor II-III loop C-region peptides: relief of Mg2+ inhibition. 1553 Jan 42
The actions of the recombinant skeletal dihydropyridine receptor II-III loop (SDCL), and the C region peptide (CS) on native
skeletal muscle ryanodine receptor
Ca2+ release channel (
RyR1
) have been examined. Three non conserved residues in the "C" region of the skeletal
DHPR
II-III loop were replaced by the equivalent cardiac residues in SDCLAFP-PTT (A739P, F741T and P742T) and single substitutions made in SDCLA-P, SDCLF-T and SDCLP-T. Wild type SDCL as well as SDCLF-T and SDCLP-T activated
RyR1
in lipid bilayers with high affinity (10 nM to 1 microM). Wild type SDCL at higher concentrations inhibited
RyR1
. In contrast, SDCLAFP-PTT and SDCLA-P inhibited the channels at >or=10 nM. The inhibitory actions of these two skeletal loop mutants were distinctly different from the cardiac II-III loop (CDCL) which, like the wild-type SDCL, activated channels. In contrast to the full loop, the triple A739P, F741T and P742T mutation in peptide CS converted the peptides' function from skeletal-like to cardiac-like. The individual A739P mutation, but not F741T or P742T, reduced the functional efficacy of CS. None of the mutations significantly altered the NMR-based secondary structure of the C residues in SDCLAFP-PTT or CS. The CS peptide and its mutants, like the cardiac CC peptide, were all partially alpha helical at low temperatures. The results show that residue A739 is critical for the functional consequences of interactions between
RyR1
and either the skeletal II-III loop or CS, but that none of A739, F741 or P742 are critical determinants of the structure of the C region.
...
PMID:Role of some unconserved residues in the "C" region of the skeletal DHPR II-III loop. 1576 32
Ca(+) sparks are rare in healthy adult mammalian skeletal muscle but may appear when adult fiber integrity is compromised, and occur in embryonic muscle but decline as the animal develops. Here we used cultured adult mouse flexor digitorum brevis muscle fibers to monitor occurrence of Ca(2+) sparks during maintenance of adult fiber morphology and during eventual fiber morphological dedifferentiation after various times in culture. Fibers cultured for up to 3 days retain normal morphology and striated appearance. Ca(2+) sparks were rare in these fibers. At 5-7 days in culture, many of the original muscle fibers exhibit sprouting and loss of striations, as well as the occurrence of spontaneous Ca(2+) sparks. The average rate of occurrence of Ca(2+) sparks is >10-fold higher after 5-7 days in culture than in days 1-3. With the use of fibers cultured for 7 days, application of the Ca(2+) channel blockers Co(2+) or nifedipine almost completely suppressed the occurrence of Ca(2+) sparks, as previously shown in embryonic fibers, suggesting that Ca(2+) sparks may be generated by similar mechanisms in dedifferentiating cultured adult fibers and in embryonic fibers before final differentiation. The sarcomeric disruption observed under transmitted light microscopy in dedifferentiating fibers was accompanied by morphological changes in the transverse (T) tubular system, as observed by fluorescence confocal imaging of both an extracellular marker dye and membrane staining dyes. Changes in T tubule morphology coincided with the appearance of Ca(2+) sparks, suggesting that Ca(2+) sparks may either be a signal for, or the result of, disruption of
DHPR
-
ryanodine receptor 1
coupling.
...
PMID:Ca2+ sparks and T tubule reorganization in dedifferentiating adult mouse skeletal muscle fibers. 1706 3
In humans aging is a complex process that determines many physical and metabolic alterations correlated to the accumulation of oxidative damage in different tissues. Sarcopenia is an age-related nonpathological condition that includes a progressive loss of mass and strength in skeletal muscle, associated with a decline in the fibers' functional capability. This condition could be correlated to abnormal reactive oxygen species (ROS) accumulation with consequent fiber oxidative damage. This complex situation is not only evident in mature muscle fibers but also in muscle resident satellite cells (involved in fiber damage repairing) in which some functional parameters, at least for that concerns the Ca(2+) homeostasis, seem to be modified. In fact, our data show that there is an age-dependent increase of lipid peroxidation, in cultured myotubes (differentiated and fused satellite cells) after 7 days of in vitro differentiation. In these substrates also the capacity of these cells to produce Ca(2+) transient in response to various stimuli (ATP, caffeine, nicotine, KCl) is, sometimes, drastically modified. In particular, the presence of an age-dependent defective status of excitation-contraction (EC) coupling apparatus is supported by a single cell Ca(2+) analysis obtained from myotubes (derived from aged muscles) in the presence of 40 mM caffeine or 40 mM KCl. The alkaloid presence induces a complete emptying of ryanodine-dependent calcium stores indicating a probable integrity both of SR-terminal cisternae and/or the specific Ca(2+) channel known as
RyR1
. However, if a sarcolemmal depolarization is induced by the addition of 40 mM KCl in the experimental medium then Ca(2+) release
RyR1
-dependent can be observed only if Ca(2+) is present in the experimental solution. These results suggest that the EC uncoupling status could be due to the alteration of the interaction between RyR and
DHPR
. The two receptors are present and functionally active in myotubes from aged donors but they are probably still not in the right localization. These results suggest that during donor's life the satellite cells undergo an aging process similar to the one observed in skeletal muscle tissue, even if they are in a quiescence status for most of the time.
...
PMID:Age-dependent effects on functional aspects in human satellite cells. 1746 Jan 97
Conformational coupling between the L-type voltage-gated Ca(2+) channel (or 1,4-dihydropyridine receptor;
DHPR
) and the ryanodine-sensitive Ca(2+) release channel of the sarcoplasmic reticulum (
RyR1
) is the mechanistic basis for excitation-contraction (EC) coupling in skeletal muscle. In this article, recent findings regarding the roles of the individual cytoplasmic domains (the amino- and carboxyl-termini, cytoplasmic loops I-II, II-III, and III-IV) of the
DHPR
alpha(1S) subunit in bi-directional communication with
RyR1
will be discussed.
...
PMID:Bridging the myoplasmic gap: recent developments in skeletal muscle excitation-contraction coupling. 1789 4
Ca2+ channels play crucial roles in cellular signal transduction and are important targets of pharmacological agents. They are also associated with auxiliary subunits exhibiting functions that are still incompletely resolved. Skeletal muscle L-type Ca2+ channels (dihydropyridine receptors, DHPRs) are specialized for the remote voltage control of type 1 ryanodine receptors (
RyR1
) to release stored Ca2+. The skeletal muscle-specific gamma subunit of the
DHPR
(gamma 1) down-modulates availability by altering its steady state voltage dependence. The effect resembles the action of certain Ca2+ antagonistic drugs that are thought to stabilize inactivated states of the
DHPR
. In the present study we investigated the cross influence of gamma 1 and Ca2+ antagonists by using wild-type (gamma+/+) and gamma 1 knockout (gamma-/-) mice. We studied voltage-dependent gating of both L-type Ca2+ current and Ca2+ release and the allosteric modulation of drug binding. We found that 10 microM diltiazem, a benzothiazepine drug, more than compensated for the reduction in high-affinity binding of the dihydropyridine agent isradipine caused by gamma 1 elimination; 5 muM devapamil [(-)D888], a phenylalkylamine Ca2+ antagonist, approximately reversed the right-shifted voltage dependence of availability and the accelerated recovery kinetics of Ca2+ current and Ca2+ release. Moreover, the presence of gamma 1 altered the effect of D888 on availability and strongly enhanced its impact on recovery kinetics demonstrating that gamma 1 and the drug do not act independently of each other. We propose that the gamma 1 subunit of the
DHPR
functions as an endogenous Ca2+ antagonist whose task may be to minimize Ca2+ entry and Ca2+ release under stress-induced conditions favoring plasmalemma depolarization.
...
PMID:The auxiliary subunit gamma 1 of the skeletal muscle L-type Ca2+ channel is an endogenous Ca2+ antagonist. 1797 88
Alternative splicing of ASI residues (Ala(3481)-Gln(3485)) in the
skeletal muscle ryanodine receptor
(
RyR1
) is developmentally regulated: the residues are present in adult ASI(+)
RyR1
, but absent in the juvenile ASI(-)
RyR1
which is over-expressed in adult myotonic dystrophy type 1 (DM1). Although this splicing switch may influence
RyR1
function in developing muscle and DM1, little is known about the properties of the splice variants. We examined excitation-contraction (EC) coupling and the structure and interactions of the ASI domain (Thr(3471)-Gly(3500)) in the splice variants. Depolarisation-dependent Ca(2+) release was enhanced by >50% in myotubes expressing ASI(-)
RyR1
compared with ASI(+)
RyR1
, although
DHPR
L-type currents and SR Ca(2+) content were unaltered, while ASI(-)
RyR1
channel function was actually depressed. The effect on EC coupling did not depend on changes in ASI domain secondary structure. Probing
RyR1
function with peptides possessing the ASI domain sequence indicated that the domain contributes to an inhibitory module in
RyR1
. The action of the peptide depended on a sequence of basic residues and their alignment in an alpha-helix adjacent to the ASI splice site. This is the first evidence that the ASI residues contribute to an inhibitory module in
RyR1
that influences EC coupling. Implications for development and DM1 are discussed.
...
PMID:Alternative splicing of RyR1 alters the efficacy of skeletal EC coupling. 1913 Nov 8
Depolarization-induced entry of divalent ions into skeletal muscle has been attributed to a process termed Excitation-Coupled Ca(2+) Entry (ECCE), which is hypothesized to require the interaction of the ryanodine receptor (
RyR1
), the L-type Ca(2+) channel (
DHPR
) and another unidentified cation channel. Thus, ECCE is absent in myotubes lacking either the
DHPR
(dysgenic) or
RyR1
(dyspedic). Furthermore, ECCE, as measured by Mn(2+) quench of Fura-2, is reconstituted by expression of a mutant
DHPR
alpha(1S) subunit (SkEIIIK) thought to be impermeable to divalent cations. Previously, we showed that the bulk of depolarization-induced Ca(2+) entry could be explained by the skeletal L-type current. Accordingly, one would predict that any Ca(2+) current similar to the endogenous current would restore such entry and that this entry would not require coupling to either the
DHPR
or
RyR1
. Here, we show that expression of the cardiac alpha(1C) subunit in either dysgenic or dyspedic myotubes does result in Ca(2+) entry similar to that ascribed to ECCE. We also demonstrate that, when potentiated by strong depolarization and Bay K 8644, SkEIIIK supports entry of Mn(2+). These results strongly support the idea that the L-type channel is the major route of Ca(2+) entry in response to repetitive or prolonged depolarization of skeletal muscle.
...
PMID:The cardiac alpha(1C) subunit can support excitation-triggered Ca2+ entry in dysgenic and dyspedic myotubes. 1962 71
In skeletal muscle, there is bidirectional signalling between the L-type Ca(2+) channel (1,4-dihydropyridine receptor;
DHPR
) and the type 1 ryanodine-sensitive Ca(2+) release channel (
RyR1
) of the sarcoplasmic reticulum (SR). In the case of "orthograde signalling" (i.e., excitation-contraction coupling), the conformation of
RyR1
is controlled by depolarization-induced conformational changes of the
DHPR
resulting in Ca(2+) release from the SR. "Retrograde coupling" is manifested as enhanced L-type current. The nature of this retrograde signal, and its dependence on
RyR1
conformation, are poorly understood. Here, we have examined L-type currents in normal myotubes after an exposure to ryanodine (200 microM, 1 h at 37 degrees C) sufficient to lock
RyR1
in a non-conducting, inactivated, conformational state. This treatment caused an increase in L-type current at less depolarized test potentials in comparison to myotubes similarly exposed to vehicle as a result of a approximately 5 mV hyperpolarizing shift in the voltage-dependence of activation. Charge movements of ryanodine-treated myotubes were also shifted to more hyperpolarizing potentials (approximately 13 mV) relative to vehicle-treated myotubes. Enhancement of the L-type current by ryanodine was absent in dyspedic (
RyR1
null) myotubes, indicating that ryanodine does not act directly on the
DHPR
. Our findings indicate that in retrograde signaling, the functional state of
RyR1
influences conformational changes of the
DHPR
involved in activation of L-type current. This raises the possibility that physiological regulators of the conformational state of
RyR1
(e.g., Ca(2+), CaM, CaMK, redox potential) may also affect
DHPR
gating.
...
PMID:Ryanodine modification of RyR1 retrogradely affects L-type Ca(2+) channel gating in skeletal muscle. 1980 26
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