Mechanisms of P(i) regulation of the skeletal muscle SR Ca(2+) release channel

Inorganic phosphate(P_i) accumulates in the fibers of actively working musclewhere it acts at various sites to modulate contraction. To characterizethe role of P_i as a regulator of the sarcoplasmic reticulum(SR) calcium (Ca²⁺) release channel, we examined the actionof P_i on purified SR Ca²⁺ release channels,isolated SR vesicles, and skinned skeletal muscle fibers. In singlechannel studies, addition of P_i to the cis chamberincreased single channel open probability (P_o;0.079 ± 0.020 in 0 P_i, 0.157 ± 0.034 in 20 mMP_i) by decreasing mean channel closed time; mean channelopen times were unaffected. In contrast, the ATP analog,,-methyleneadenosine 5'-triphosphate (AMP-PCP), enhancedP_o by increasing single channel open time anddecreasing channel closed time. P_i stimulation of[³H]ryanodine binding by SR vesicles wassimilar at all concentrations of AMP-PCP, suggesting P_i andadenine nucleotides act via independent sites. In skinned musclefibers, 40 mM P_i enhanced Ca²⁺-inducedCa²⁺ release, suggesting an in situ stimulation ofthe release channel by high concentrations of P_i. Ourresults support the hypothesis that P_i may be an importantendogenous modulator of the skeletal muscle SR Ca²⁺ releasechannel under fatiguing conditions in vivo, acting via a mechanismdistinct from adenine nucleotides.

     

Measurement of RyR permeability reveals a role of calsequestrin in termination of SR Ca(2+) release in skeletal muscle

The mechanisms that terminate Ca(2+) release from the sarcoplasmic reticulum are not fully understood. D4cpv-Casq1 (Sztretye et al. 2011. J. Gen. Physiol. doi:10.1085/jgp.201010591) was used in mouse skeletal muscle cells under voltage clamp to measure free Ca(2+) concentration inside the sarcoplasmic reticulum (SR), [Ca(2+)](SR), simultaneously with that in the cytosol, [Ca(2+)](c), during the response to long-lasting depolarization of the plasma membrane. The ratio of Ca(2+) release flux (derived from [Ca(2+)](c)(t)) over the gradient that drives it (essentially equal to [Ca(2+)](SR)) provided directly, for the first time, a dynamic measure of the permeability to Ca(2+) of the releasing SR membrane. During maximal depolarization, flux rapidly rises to a peak and then decays. Before 0.5 s, [Ca(2+)](SR) stabilized at ～35% of its resting level; depletion was therefore incomplete. By 0.4 s of depolarization, the measured permeability decayed to ～10% of maximum, indicating ryanodine receptor channel closure. Inactivation of the t tubule voltage sensor was immeasurably small by this time and thus not a significant factor in channel closure. In cells of mice null for Casq1, permeability did not decrease in the same way, indicating that calsequestrin (Casq) is essential in the mechanism of channel closure and termination of Ca(2+) release. The absence of this mechanism explains why the total amount of calcium releasable by depolarization is not greatly reduced in Casq-null muscle (Royer et al. 2010. J. Gen. Physiol. doi:10.1085/jgp.201010454). When the fast buffer BAPTA was introduced in the cytosol, release flux became more intense, and the SR emptied earlier. The consequent reduction in permeability accelerated as well, reaching comparable decay at earlier times but comparable levels of depletion. This observation indicates that [Ca(2+)](SR), sensed by Casq and transmitted to the channels presumably via connecting proteins, is determinant to cause the closure that terminates Ca(2+) release.     

RyR3 amplifies RyR1-mediated Ca(2+)-induced Ca(2+) release in neonatal mammalian skeletal muscle

The neonatal mammalian skeletal muscle contains both type 1 and type 3 ryanodine receptors (RyR1 and RyR3) located in the sarcoplasmic reticulum membrane. An allosteric interaction between RyR1 and dihydropyridine receptors located in the plasma membrane mediates voltage-induced Ca(2+) release (VICR) from the sarcoplasmic reticulum. RyR3, which disappears in adult muscle, is not involved in VICR, and the role of the transiently expressed RyR3 remains elusive. Here we demonstrate that RyR1 participates in both VICR and Ca(2+)-induced Ca(2+) release (CICR) and that RyR3 amplifies RyR1-mediated CICR in neonatal skeletal muscle. Confocal measurements of intracellular Ca(2+) in primary cultured mouse skeletal myotubes reveal active sites of Ca(2+) release caused by peripheral coupling between dihydropyridine receptors and RyR1. In myotubes lacking RyR3, the peripheral VICR component is unaffected, and RyR1s alone are able to support inward CICR propagation in most cells at an average speed of approximately 190 microm/s. With the co-presence of RyR1 and RyR3 in wild-type cells, unmitigated radial CICR propagates at 2,440 microm/s. Because neonatal skeletal muscle lacks a well developed transverse tubule system, the RyR3 reinforcement of CICR seems to ensure a robust, uniform, and synchronous activation of Ca(2+) release throughout the cell body. Such functional interplay between RyR1 and RyR3 can serve important roles in Ca(2+) signaling of cell differentiation and muscle contraction.     

Calcium currents of frog and insect skeletal muscle fibres measured during voltage clamp

Both vertebrate and invertebrate skeletal muscle fibres have Ca2+ permeability mechanisms which are turned on by depolarization of the surface membrane. In frog muscle, Ca currents are extremely slow and will be scarcely activated during the action potential that normally elicits a twitch. This Ca permeability cannot therefore play any substantial, direct role in excitation--contraction coupling. In insect (Carausius morosus) muscle, Ca currents activate within milliseconds of depolarization, even at low temperature, and may well play at least a triggering role in excitation--contraction coupling. These Ca currents show saturation with increasing [Ca]0, while the instantaneous current--voltage relation rectifies inwards, as expected from a very low [Ca]i. The Ca channel is permeable to Sr2+ and Ba2+. Inactivation of Ca currents under a maintained depolarization depends on Ca2+ carrying inward current, however, rather than on the depolarization itself.     

Ca(2+)-dependent interaction between FKBP12 and calcineurin regulates activity of the Ca(2+) release channel in skeletal muscle

Calcineurin is a Ca(2+) and calmodulin-dependent protein phosphatase with diverse cellular functions. Here we examined the physical and functional interactions between calcineurin and ryanodine receptor (RyR) in a C2C12 cell line derived from mouse skeletal muscle. Coimmunoprecipitation experiments revealed that the association between RyR and calcineurin exhibits a strong Ca(2+) dependence. This association involves a Ca(2+) dependent interaction between calcineurin and FK506-binding protein (FKBP12), an accessory subunit of RyR. Pretreatment with cyclosporin A, an inhibitor of calcineurin, enhanced the caffeine-induced Ca(2+) release (CICR) in C2C12 cells. This effect was similar to those of FK506 and rapamycin, two drugs known to cause dissociation of FKBP12 from RyR. Overexpression of a constitutively active form of calcineurin in C2C12 cells, DeltaCnA(391-521) (deletion of the last 131 amino acids from calcineurin), resulted in a decrease in CICR. This decrease in CICR activity was partially recovered by pretreatment with cyclosporin A. Furthermore, overexpression of an endogenous calcineurin inhibitor (cain) or an inactive form of calcineurin (DeltaCnA(H101Q)) in C2C12 cells resulted in up-regulation of CICR. Taken together, our data suggest that a trimeric-interaction among calcineurin, FKBP12, and RyR is important for the regulation of the RyR channel activity and may play an important role in the Ca(2+) signaling of muscle contraction and relaxation.     

T-tubule depolarization-induced SR Ca2+ release is controlled by dihydropyridine receptor- and Ca(2+)-dependent mechanisms in cell homogenates from rabbit skeletal muscle

In vertebrate skeletal muscle, the voltage-dependent mechanism of rapid sarcoplasmic reticulum (SR) Ca2+ release, commonly referred to as excitation-contraction (EC) coupling, is believed to be mediated by physical interaction between the transverse (T)-tubule voltage-sensing dihydropyridine receptor (DHPR) and the SR ryanodine receptor (RyR)/Ca2+ release channel. In this study, differential T-tubule and SR membrane monovalent ion permeabilities were exploited with the use of an ion-replacement protocol to study T-tubule depolarization-induced SR 45Ca2+ release from rabbit skeletal muscle whole-cell homogenates. Specificity of Ca2+ release was ascertained with the use of the DHPR antagonists D888, nifedipine and PN200-110. In the presence of the "slow" complexing Ca2+ buffer EGTA, homogenates exhibited T-tubule depolarization-induced Ca2+ release comprised of an initial rapid phase followed by a slower release phase. During the rapid phase, approximately 20% of the total sequestered Ca2+ (approximately 30 nmol 45Ca2+/mg protein), corresponding to 100% of the caffeine-sensitive Ca2+ pool, was released within 50 ms. Rapid release could be inhibited fourfold by D888. Addition to release media of the "fast" complexing Ca2+ buffer BAPTA, at concentrations > or = 4 mM, nearly abolished rapid Ca2+ release, suggesting that most was Ca2+ dependent. Addition of millimolar concentrations of either Ca2+ or Mg2+ also greatly reduced rapid Ca2+ release. These results show that T-tubule depolarization-induced SR Ca2+ release from rabbit skeletal muscle homogenates is controlled by T-tubule membrane potential- and by Ca(2+)- dependent mechanisms.     

Evidence for a role of C-terminus in Ca(2+) inactivation of skeletal muscle Ca(2+) release channel (ryanodine receptor).

Six chimeras of the skeletal muscle (RyR1) and cardiac muscle (RyR2) Ca(2+) release channels (ryanodine receptors) previously used to identify RyR1 dihydropyridine receptor interactions [Nakai et al. (1998) J. Biol. Chem. 273, 13403] were expressed in HEK293 cells to assess their Ca(2+) dependence in [(3)H]ryanodine binding and single channel measurements. The results indicate that the C-terminal one-fourth has a major role in Ca(2+) activation and inactivation of RyR1. Further, our results show that replacement of RyR1 regions with corresponding RyR2 regions can result in loss and/or reduction of [(3)H]ryanodine binding affinity while maintaining channel activity.     

Patch-clamp recording of charge movement, Ca(2+) current, and Ca(2+) transients in adult skeletal muscle fibers

Intramembrane charge movement (Q), Ca(2+) conductance (G(m)) through the dihydropyridine-sensitive L-type Ca(2+) channel (DHPR) and intracellular Ca(2+) fluorescence (F) have been recorded simultaneously in flexor digitorum brevis muscle fibers of adult mice, using the whole-cell configuration of the patch-clamp technique. The voltage distribution of Q was fitted to a Boltzmann equation; the Q(max), V(1/2Q), and effective valence (z(Q)) values were 41 +/- 3.1 nC/&mgr;F, -17.6 +/- 0.7 mV, and 2.0 +/- 0.12, respectively. V(1/2G) and z(G) values were -0.3 +/- 0.06 mV and 5.6 +/- 0.34, respectively. Peak Ca(2+) transients did not change significantly after 30 min of recording. F was fit to a Boltzmann equation, and the values for V(F1/2) and z(F) were 6.2 +/- 0.04 mV and 2.4, respectively. F was adequately fit to the fourth power of Q. These results demonstrate that the patch-clamp technique is appropriate for recording Q, G(m), and intracellular [Ca(2+)] simultaneously in mature skeletal muscle fibers and that the voltage distribution of the changes in intracellular Ca(2+) can be predicted by a Hodgkin-Huxley model.     

Two domains in dihydropyridine receptor activate the skeletal muscle Ca(2+) release channel

The II-III cytoplasmic loop of the skeletal muscle dihydropyridine receptor (DHPR) alpha(1)-subunit is essential for skeletal-type excitation-contraction coupling. Single channel and [(3)H]ryanodine binding studies with a full-length recombinant peptide (p(666-791)) confirmed that this region specifically activates skeletal muscle Ca2+ release channels (CRCs). However, attempts to identify shorter domains of the II-III loop specific for skeletal CRC activation have yielded contradictory results. We assessed the specificity of the interaction of five truncated II-III loop peptides by comparing their effects on skeletal and cardiac CRCs in lipid bilayer experiments; p(671-680) and p(720-765) specifically activated the submaximally Ca2+-activated skeletal CRC in experiments using both mono and divalent ions as current carriers. A third peptide, p(671-690), showed a bimodal activation/inactivation behavior indicating a high-affinity activating and low-affinity inactivating binding site. Two other peptides (p(681-690) and p(681-685)) that contained an RKRRK-motif and have previously been suggested in in vitro studies to be important for skeletal-type E-C coupling, failed to specifically stimulate skeletal CRCs. Noteworthy, p(671-690), p(681-690), and p(681-685) induced similar subconductances and long-lasting channel closings in skeletal and cardiac CRCs, indicating that these peptides interact in an isoform-independent manner with the CRCs.     

Characteristics of phosphate-induced Ca(2+) efflux from the SR in mechanically skinned rat skeletal muscle fibers

ATP is a candidate enteric inhibitory neurotransmitterin visceral smooth muscles. ATP hyperpolarizes visceral muscles via activation of small-conductance, Ca²⁺-activatedK⁺ (SK) channels. Coupling between ATP stimulation and SKchannels may be mediated by localized Ca²⁺ release.Isolated myocytes of the murine colon produced spontaneous, localizedCa²⁺ release events. These events corresponded tospontaneous transient outward currents (STOCs) consisting ofcharybdotoxin (ChTX)-sensitive and -insensitive events.ChTX-insensitive STOCs were inhibited by apamin. LocalizedCa²⁺ transients were not blocked by ryanodine, but theseevents were reduced in magnitude and frequency by xestospongin C(Xe-C), a blocker of inositol 1,4,5-trisphosphate receptors. Thus wehave termed the localized Ca²⁺ events in colonic myocytes"Ca²⁺ puffs." The P_2Y receptor agonist2-methylthio-ATP (2-MeS-ATP) increased the intensity and frequency ofCa²⁺ puffs. 2-MeS-ATP also increased STOCs in associationwith the increase in Ca²⁺ puffs.Pyridoxal-phospate-6-azophenyl-2',4'-disculfonic acid tetrasodium, aP₂ receptor inhibitor, blocked responses to 2-MeS-ATP. Spontaneous Ca²⁺ transients and the effects of 2-MeS-ATP onCa²⁺ puffs and STOCs were blocked by U-73122, an inhibitorof phospholipase C. Xe-C and ryanodine also blocked responses to2-MeS-ATP, suggesting that, in addition to release from IP₃receptor-operated stores, ryanodine receptors may be recruited duringagonist stimulation to amplify release of Ca²⁺. These datasuggest that localized Ca²⁺ release modulatesCa²⁺-dependent ionic conductances in the plasma membrane.Localized Ca²⁺ release may contribute to the electricalresponses resulting from purinergic stimulation.

     

A mechanism for both capacitative Ca(2+) entry and excitation-contraction coupled Ca(2+) release by the sarcoplasmic reticulum of skeletal muscle cells

We have previously established that L6 skeletal muscle cell cultures display capacitative calcium entry (CCE), a phenomenon established with other cells in which Ca(2+) uptake from outside cells increases when the endoplasmic reticulum (sarcoplasmic reticulum in muscle, or SR) store is decreased. Evidence for CCE rested on the use of thapsigargin (Tg), an inhibitor of the SR CaATPase and consequently transport of Ca(2+) from cytosol to SR, and measurements of cytosolic Ca(2+). When Ca(2+) is added to Ca(2+)-free cells in the presence of Tg, the measured cytosolic Ca(2+) rises. This has been universally interpreted to mean that as SR Ca(2+) is depleted, exogenous Ca(2+) crosses the plasma membrane, but accumulates in the cytosol due to CaATPase inhibition. Our goal in the present study was to examine CCE in more detail by measuring Ca(2+) in both the SR lumen and the cytosol using established fluorescent dye techniques for both. Surprisingly, direct measurement of SR Ca(2+) in the presence of Tg showed an increase in luminal Ca(2+) concentration in response to added exogenous Ca(2+). While we were able to reproduce the conventional demonstration of CCE-an increase of Ca(2+) in the cytosol in the presence of thapsigargin-we found that this process was inhibited by the prior addition of ryanodine (Ry), which inhibits the SR Ca(2+) release channel, the ryanodine receptor (RyR). This was also unexpected if Ca(2+) enters the cytosol first. When Ca(2+) was added prior to Ry, the later was unable to exert any inhibition. This implies a competitive interaction between Ca(2+) and Ry at the RyR. In addition, we found a further paradox: we had previously found Ry to be an uncompetitive inhibitor of Ca(2+) transport through the RyR during excitation-contraction coupling. We also found here that high concentrations of Ca(2+) inhibited its own uptake, a known feature of the RyR. We confirmed that Ca(2+) enters the cells through the dihydropyridine receptor (DHPR, also known as the L-channel) by demonstrating inhibition by diltiazem. A previous suggestion to the contrary had used Mn(2+) in place of direct Ca(2+) measurements; we showed that Mn(2+) was not inhibited by diltiazem and was not capacitative, and thus not an appropriate probe of Ca(2+) flow in muscle cells. Our findings are entirely explained by a new model whereby Ca(2+) enters the SR from the extracellular space directly through a combined channel formed from the DHPR and the RyR. These are known to be in close proximity in skeletal muscle. Ca(2+) subsequently appears in the cytosol by egress through a separate, unoccupied RyR, explaining Ry inhibition. We suggest that upon excitation, the DHPR, in response to the electrical field of the plasma membrane, shifts to an erstwhile-unoccupied receptor, and Ca(2+) is released from the now open RyR to trigger contraction. We discuss how this model also resolves existing paradoxes in the literature, and its implications for other cell types.     

Voltage-independent changes in L-type Ca(2+) current uncoupled from SR Ca(2+) release in cardiac myocytes

To determine the effect of voltage-independent alterations of L-type Ca(2+) current (I(Ca)) on the sarcoplasmic reticular (SR) Ca(2+) release in cardiac myocytes, we measured I(Ca) and cytosolic Ca(2+) transients (Ca(i)(2+); intracellular Ca(2+) concentration) in voltage-clamped rat ventricular myocytes during 1) an abrupt increase of extracellular [Ca(2+)] (Ca(o)(2+)) or 2) application of 1 microM FPL-64176, a Ca(2+) channel agonist, to selectively alter I(Ca) in the absence of changes in SR Ca(2+) loading. On the first depolarization in higher Ca(o)(2+), peak I(Ca) was increased by 46 +/- 6% (P < 0.001), but the increases in the maximal rate of rise of Ca(i)(2+) (dCa(i)(2+)/dt(max), where t is time; an index of SR Ca(2+) release flux) and the Ca(i)(2+) transient amplitude were not significant. Rapid exposure to FPL-64176 greatly slowed inactivation of I(Ca), increasing its time integral by 117 +/- 8% (P < 0.001) without significantly increasing peak I(Ca), dCa(i)(2+)/dt(max), or amplitude of the corresponding Ca(i)(2+) transient. Prolongation of exposure to higher Ca(o)(2+) or FPL-64176 did not further increase peak I(Ca) but greatly increased dCa(i)(2+)/dt(max), Ca(i)(2+) transient amplitude, and the gain of Ca(2+) release (dCa(i)(2+)/dt(max)/I(Ca)), evidently due to augmentation of the SR Ca(2+) loading. Also, the time to peak dCa(i)(2+)/dt(max) was significantly increased in the continuous presence of higher Ca(o)(2+) (by 37 +/- 5%, P < 0.001) or FPL-64176 (by 63 +/- 5%, P < 0.002). Our experiments provide the first evidence of a marked disparity between an increased peak I(Ca) and the corresponding SR Ca(2+) release. We attribute this to saturation of the SR Ca(2+) release flux as predicted by local control theory. Prolongation of the SR Ca(2+) release flux, caused by combined actions of a larger I(Ca) and maximally augmented SR Ca(2+) loading, might reflect additional Ca(2+) release from corbular SR.     

o-Phthalaldehyde activates the Ca(2+) release mechanism from skeletal muscle sarcoplasmic reticulum.

o-Phthalaldehyde (OPA) is a bifunctional reagent that forms an isoindole derivative by reacting with cysteine and lysine residues separated by approximately 0.3 nm. OPA inhibits sarcoplasmic reticulum (SR) Ca(2+)-ATPase activity at low micromolar concentrations and induces Ca(2+) release from actively loaded SR vesicles by activating the ryanodine receptor from fast twitch skeletal muscle. Both ryanodine binding and single-channel activity show a biphasic concentration dependence. At low OPA concentrations (<100 microM), ryanodine binding and single channel activity are stimulated, while at higher concentrations, a time-dependent sequential activation and inhibition of receptor binding is observed. Activation is characterized by a Ca(2+)-independent increase in maximal receptor occupancy. Data are presented to support a model in which Ca(2+) channel and ryanodine binding activity are enhanced due to an intramolecular cross-linking of nearby lysine and nonhyperreactive cysteine residues. OPA complexation with endogenous lysine residue(s) is critical for receptor activation.     

Voltage and Ca(2+) dependence of pre-steady-state currents of the Na-Ca exchanger generated by Ca(2+) concentration jumps

The Ca(2+) concentration and voltage dependence of the relaxation kinetics of the Na-Ca exchanger after a Ca(2+) concentration jump was measured in excised giant membrane patches from guinea pig heart. Ca(2+) concentration jumps on the cytoplasmic side were achieved by laser flash-induced photolysis of DM-nitrophen. In the Ca-Ca exchange mode a transient inward current is generated. The amplitude and the decay rate of the current saturate at concentrations >10 microM. The integrated current signal, i.e., the charge moved is fairly independent of the amount of Ca(2+) released. The amount of charge translocated increases at negative membrane potentials, whereas the decay rate constant shows no voltage dependence. It is suggested that Ca(2+) translocation occurs in at least four steps: intra- and extracellular Ca(2+) binding and two intramolecular transport steps. Saturation of the amplitude and of the relaxation of the current can be explained if the charge translocating reaction step is preceded by two nonelectrogenic steps: Ca(2+) binding and one conformational transition. Charge translocation in this mode is assigned to one additional conformational change which determines the equilibrium distribution of states. In the Na-Ca exchange mode, the stationary inward current depends on the cytoplasmic Ca(2+) concentration and voltage. The K(m) for Ca(2+) is 4 microM for guinea pig and 10 microM for rat myocytes. The amplitude of the pre-steady-state current and its relaxation saturate with increasing Ca(2+) concentrations. In this mode the relaxation is voltage dependent.     

Effects of quercetin on single Ca(2+) release channel behavior of skeletal muscle

Quercetin, a bioflavonoid, is known to affect Ca(2+) fluxes in sarcoplasmic reticulum, although its direct effect on Ca(2+) release channel (CRC) in sarcoplasmic reticulum has remained to be elucidated. The present study examined the effect of quercetin on the behavior of single skeletal CRC in planar lipid bilayer. The effect of caffeine was also studied for comparison. At very low [Ca(2+)](cis) (80 pM), quercetin activated CRC marginally, whereas at elevated [Ca(2+)](cis) (10 microM), both open probability (P(o)) and sensitivity to the drug increased markedly. Caffeine showed a similar tendency. Analysis of lifetimes for single CRC showed that quercetin and caffeine led to different mean open-time and closed-time constants and their proportions. Addition of 10 microM ryanodine to CRC activated by quercetin or caffeine led to the typical subconductance state (approximately 54%) and a subsequent addition of 5 microM ruthenium red completely blocked CRC activity. When 6 microM quercetin and 3 mM caffeine were added together to the cis side of CRC, a time-dependent increase of P(o) was observed (from mode 1 (0.376 +/- 0.043, n = 5) to mode 2 (0.854 +/- 0.062, n = 5)). On the other hand, no further activation was observed when quercetin was added after caffeine. Quercetin affected only the ascending phase of the bell-shaped Ca(2+) activation/inactivation curve, whereas caffeine affected both ascending and descending phases. [(3)H]ryanodine binding to sarcoplasmic reticulum showed that channel activity increased more by both quercetin and caffeine than by caffeine alone. These characteristic differences in the modes of activation of CRC by quercetin and caffeine suggest that the channel activation mechanisms and presumably the binding sites on CRC are different for the two drugs.     

Myogenic contraction in rat skeletal muscle arterioles: smooth muscle membrane potential and Ca(2+) signaling

The present studies examined relationships between intraluminal pressure, membrane potential (E(m)), and myogenic tone in skeletal muscle arterioles. Using pharmacological interventions targeting Ca(2+) entry/release mechanisms, these studies also determined the role of Ca(2+) pathways and E(m) in determining steady-state myogenic constriction. Studies were conducted in isolated and cannulated arterioles under zero flow. Increasing intraluminal pressure (0-150 mmHg) resulted in progressive membrane depolarization (-55.3 +/- 4.1 to -29.4 +/- 0.7 mV) that exhibited a sigmoidal relationship between extent of myogenic constriction and E(m). Thus, despite further depolarization, at pressures >70 mmHg, little additional vasoconstriction occurred. This was not due to an inability of voltage-operated Ca(2+) channels to be activated as KCl (75 mM) evoked depolarization and vasoconstriction at 120 mmHg. Nifedipine (1 microM) and cyclopiazonic acid (30 microM) significantly attenuated established myogenic tone, whereas inhibition of inositol 1,4,5-trisphosphate-mediated Ca(2+) release/entry by 2-aminoethoxydiphenylborate (50 microM) had little effect. Combinations of the Ca(2+) entry blockers with the sarcoplasmic reticulum (SR) inhibitor caused a total loss of tone, suggesting that while depolarization-mediated Ca(2+) entry makes a significant contribution to myogenic tone, an interaction between Ca(2+) entry and SR Ca(2+) release is necessary for maintenance of myogenic constriction. In contrast, none of the agents, in combination or alone, altered E(m), demonstrating the downstream role of Ca(2+) mobilization relative to changes in E(m). Large-conductance Ca(2+)-activated K(+) channels modulated E(m) to exert a small effect on myogenic tone, and consistent with this, skeletal muscle arterioles appeared to show an inherently steep relationship between E(m) and extent of myogenic tone. Collectively, skeletal muscle arterioles exhibit complex relationships between E(m), Ca(2+) availability, and myogenic constriction that impact on the tissue's physiological function.     

Mutation of divergent region 1 alters caffeine and Ca(2+) sensitivity of the skeletal muscle Ca(2+) release channel (ryanodine receptor)

Replacement of amino acids 4187-4628 in the skeletal muscle Ca(2+) release channel (skeletal ryanodine receptor (RyR1)), including nearly all of divergent region 1 (amino acids 4254-4631), with the corresponding cardiac ryanodine receptor (RyR2) sequence leads to increased sensitivity of channel activation by caffeine and Ca(2+) and to decreased sensitivity of channel inactivation by elevated Ca(2+) (Du, G. G., and MacLennan, D. H. (1999) J. Biol. Chem. 274, 26120-26126). In further investigations, this region was subdivided by the construction of new chimeras, and alterations in channel function were detected by measurement of the caffeine dependence of in vivo Ca(2+) release and the Ca(2+) dependence of [(3)H]ryanodine binding. Chimera RF10a (amino acids 4187-4381) had a lower EC(50) value for activation by caffeine, and RF10c (4557-4628) had a higher EC(50) value, whereas the EC(50) value for chimera RF10b (4382-4556) was unchanged. Chimeras RF10b and RF10c were more sensitive to activation by Ca(2+), whereas RF10a was less sensitive to inactivation by Ca(2+), implicating RF10b and RF10c in Ca(2+) activation and RF10a in Ca(2+) inactivation. Deletion of much of divergent region 1 sequence to create mutant Delta4274-4535 led to higher caffeine and Ca(2+) sensitivity of channel activation and to lower Ca(2+) sensitivity for inactivation. Thus, deletion results demonstrate that caffeine, Ca(2+), and ryanodine binding sites are not located in amino acids 4274-4535. Nevertheless, the properties of the deletion and chimeric mutants demonstrate that amino acids 4274-4535 and three shorter sequences in this region (F10a, amino acids 4187-4381; F10b, 4382-4556; and F10c, 4557-4628) in RyR1 modulate Ca(2+) and caffeine sensitivity of the Ca(2+) release channel.     

A negatively charged region of the skeletal muscle ryanodine receptor is involved in Ca(2+)-dependent regulation of the Ca(2+) release channel

The ryanodine receptor/Ca(2+) release channels from skeletal (RyR1) and cardiac (RyR2) muscle cells exhibit different inactivation profiles by cytosolic Ca(2+). D3 is one of the divergent regions between RyR1 (amino acids (aa) 1872-1923) and RyR2 (aa 1852-1890) and may contain putative binding site(s) for Ca(2+)-dependent inactivation of RyR. To test this possibility, we have deleted the D3 region from RyR1 (DeltaD3-RyR1), residues 1038-3355 from RyR2 (Delta(1038-3355)-RyR2) and inserted the skeletal D3 into Delta(1038-3355)-RyR2 to generate sD3-RyR2. The channels formed by DeltaD3-RyR1 and Delta(1038-3355)-RyR2 are resistant to inactivation by mM [Ca(2+)], whereas the chimeric sD3-RyR2 channel exhibits significant inactivation at mM [Ca(2+)]. The DeltaD3-RyR1 channel retains its sensitivity to activation by caffeine, but is resistant to inactivation by Mg(2+). The data suggest that the skeletal D3 region is involved in the Ca(2+)-dependent regulation of the RyR1 channel.     

Effect of lactate on depolarization-induced Ca(2+) release in mechanically skinned skeletal muscle fibers

Itis unclear whether accumulation of lactate in skeletal muscle fibersduring intense activity contributes to muscle fatigue. Usingmechanically skinned fibers from rat and toad muscle, we were able toexamine the effect of L(+)-lactate onexcitation-contraction coupling independently of other metabolicchanges. We investigated the effects of lactate on the contractileapparatus, caffeine-induced Ca²⁺ release from thesarcoplasmic reticulum, and depolarization-induced Ca²⁺release. Lactate (15 or 30 mM) had only a small inhibitory effect directly on the contractile apparatus and caused appreciable(20-35%) inhibition of caffeine-induced Ca²⁺ release,seemingly by a direct effect on the Ca²⁺ release channels.However, 15 mM lactate had no detectable effect on Ca²⁺release when it was triggered by the normal voltage sensor mechanism, and 30 mM lactate reduced such release by only <10%. These results indicate that lactate has only a relatively small inhibitory effect onnormal excitation-contraction coupling, indicating that lactate accumulation per se is not a major factor in muscle fatigue.