Fast release of 45Ca2+ induced by inositol 1,4,5-trisphosphate and Ca2+ in the sarcoplasmic reticulum of rabbit skeletal muscle: evidence for two types of Ca2+ release channels.

The kinetics of Ca2+ release induced by the second messenger D-myoinositol 1,4,5 trisphosphate (IP3), by the hydrolysis-resistant analogue D-myoinositol 1,4,5 trisphosphorothioate (IPS3), and by micromolar Ca2+ were resolved on a millisecond time scale in the junctional sarcoplasmic reticulum (SR) of rabbit skeletal muscle. The total Ca2+ mobilized by IP3 and IPS3 varied with concentration and with time of exposure. Approximately 5% of the 45Ca2+ passively loaded into the SR was released by 2 microM IPS3 in 150 ms, 10% was released by 10 microM IPS3 in 100 ms, and 20% was released by 50 microM IPS3 in 20 ms. Released 45Ca2+ reached a limiting value of approximately 30% of the original load at a concentration of 10 microM IP3 or 25-50 microM IPS3. Ca(2+)-induced Ca2+ release (CICR) was studied by elevating the extravesicular Ca2+ while maintaining a constant 5-mM intravesicular 45Ca2+. An increase in extravesicular Ca2+ from 7 nM to 10 microM resulted in a release of 55 +/- 7% of the passively loaded 45Ca2+ in 150 ms. CICR was blocked by 5 mM Mg2+ or by 10 microM ruthenium red, but was not blocked by heparin at concentrations as high as 2.5 mg/ml. In contrast, the release produced by IPS3 was not affected by Mg2+ or ruthenium red but was totally inhibited by heparin at concentrations of 2.5 mg/ml or lower. The release produced by 10 microM Ca2+ plus 25 microM IPS3 was similar to that produced by 10 microM Ca2+ alone and suggested that IP3-sensitive channels were present in SR vesicles also containing ruthenium red-sensitive Ca2+ release channels. The junctional SR of rabbit skeletal muscle may thus have two types of intracellular Ca2+ releasing channels displaying fast activation kinetics, namely, IP3-sensitive and Ca(2+)-sensitive channels.     

Ca-release by phosphoinositides from sarcoplasmic reticulum of frog skeletal muscle

To clarify the biological role of phosphoinositides including inositol trisphosphate (IP3) in the skeletal muscle, we examined the Ca-releasing action on the heavy fraction of sarcoplasmic reticulum (HFSR) from bullfrog skeletal muscle of IP3, phosphatidylinositol monophosphate (PIP), phosphatidylinositol 4,5-bisphosphate (PIP2), and glycerophosphoinositol 4,5-bisphosphate (GPIP2). Only PIP2 caused dose-dependent Ca release. IP3 (up to 55 microM), PIP (up to 37 microM), and GPIP2 (up to 33 microM) were ineffective. The PIP2-induced Ca release is due to the direct action of PIP2, but not its metabolite(s). The properties of the PIP2-induced Ca release are unique and cannot be accounted for by the Ca release mechanisms already reported, such as Ca2+-induced, ionic substitution-induced, or IP3-induced Ca release. The rate of the PIP2-induced Ca release, however, is so slow that it may have no physiological relevance unless stimulating factors or agents exist.     

Inositol triphosphate-induced Ca2+ release from human platelet membranes

Inositol (1,4,5) triphosphate (IP3) was observed to induce release of sequestered Ca2+ from crude human platelet membranes. This activity was also shown to be present in purified membranes enriched in Ca2+-ATPase activity. Maximal Ca2+ release occurred at 8 microM IP3 and half maximal activity was at 0.4 microM. Release was quite rapid and was complete by 40 s. Released Ca2+ was pumped back into the membrane vesicles and the rate of this reuptake was increased by the presence of phosphate. These results demonstrate that internal platelet membranes that possess an active Ca2+-pump will release sequestered Ca2+ in the presence of the second messenger IP3. IP3 did not induce release of Ca2+ from skeletal muscle sarcoplasmic reticulum when ATP was present.     

Ca2+- and inositol-1,4,5-triphosphate induced release of Ca2+ in the microsomal fraction of the rat brain

Using the fluorescent probes, Quin 2 and chlortetracycline, a comparative study of the Ca2+ and inositol-1.4.5-triphosphate (IP3)-induced Ca2+ release from rabbit skeletal muscle sarcoplasmic reticulum (SR) terminal cisterns and rat brain microsomal vesicles was carried out. It was shown that Ca2+ release from rat brain microsomal vesicles is induced both by IP3 and Ca2+, whereas that in SR terminal cisterns is induced only by Ca2+. Data from chlorotetracycline fluorescence analysis revealed that CaCl2 (50 microM) causes the release of 15-20% and 40-50% of the total Ca2+ pool accumulated in rat brain microsomal vesicles and rabbit SR terminal cisterns, respectively. Using Quin 2, it was found that IP3 used at the optimal concentration (1.5 mM) caused the release of 0.4-0.6 nmol of Ca2+ per mg microsomal protein, which makes up to 10-15% of the total Ca2+ pool. IP3 does not induce Ca2+ release in SR. Preliminary release of Ca2+ from brain microsomes induced by IP3 diminishes the liberation of this cation induced by Ca2+. It is suggested that brain microsomes contain a Ca2+ pool which is exhausted under the action of the both effectors, Ca2+ and IP3.     

Role of inositol 1,4,5-trisphosphate in excitation-contraction coupling in skeletal muscle

The sarcoplasmic reticulum (SR) of skeletal muscle is an intracellular membranous network that controls the myoplasmic Ca2+ concentration and the contraction-relaxation cycle. Ca2+ release from the terminal cisternae (TC) region of the SR evokes contraction. How electrical depolarization of the transverse tubule is linked to Ca2+ release from the junctionally associated TC is still largely unknown. Independent evidence has been recently obtained indicating that either inositol trisphosphate (IP3) or (and) Ca2+ is (are) the chemical transmitter(s) of excitation-contraction coupling. Here we outline the experimental data in support of each transmitter and discuss possible interactive roles of Ca2+ and IP3.     

No evidence for inositol 1,4,5-trisphosphate-dependent Ca2+ release in isolated fibers of adult mouse skeletal muscle

The presence and role of functional inositol 1,4,5-trisphosphate (IP(3)) receptors (IP(3)Rs) in adult skeletal muscle are controversial. The current consensus is that, in adult striated muscle, the relative amount of IP(3)Rs is too low and the kinetics of Ca(2+) release from IP(3)R is too slow compared with ryanodine receptors to contribute to the Ca(2+) transient during excitation-contraction coupling. However, it has been suggested that IP(3)-dependent Ca(2+) release may be involved in signaling cascades leading to regulation of muscle gene expression. We have reinvestigated IP(3)-dependent Ca(2+) release in isolated flexor digitorum brevis (FDB) muscle fibers from adult mice. Although Ca(2+) transients were readily induced in cultured C2C12 muscle cells by (a) UTP stimulation, (b) direct injection of IP(3), or (c) photolysis of membrane-permeant caged IP(3), no statistically significant change in calcium signal was detected in adult FDB fibers. We conclude that the IP(3)-IP(3)R system does not appear to affect global calcium levels in adult mouse skeletal muscle.     

Phosphatidylinositol 4,5-bisphosphate-induced Ca2+ release from skeletal muscle sarcoplasmic reticulum terminal cisternal membranes. Ca2+ flux and single channel studies.

We report here that the inositol 1,4,5-trisphosphate (IP3) precursor, L-alpha-phosphatidylinositol 4,5-bisphosphate (PIP2) is a potent molecule (1 microM) which activates the ryanodine-sensitive Ca2+ release channel from rabbit skeletal muscle terminal cisternae incorporated into a phospholipid bilayer. It also stimulates Ca2+ release from these membrane vesicles. Therefore, it may play a modulating role in excitation-contraction coupling. In the bilayer, PIP2 added on the cytoplasmic side increased the mean channel opening probability 2-12-fold in the presence and absence of physiological Mg2+ and ATP. From flux studies, PIP2-induced Ca2+ release, occurring through the ryanodine-sensitive Ca2+ release channel, displayed saturation kinetics. The rate of Ca2+ release induced by PIP2 was approximately greater than 50% slower than the rates induced by other agents (e.g. caffeine, Ca2+, ATP). PIP2, and not IP3, effectively elicited Ca2+ release from terminal cisternae. On the contrary, IP3, and not PIP2, specifically mediated Ca2+ release from dog brain cerebellum microsomes, where IP3 receptors are known to be found. The PIP2-induced Ca2+ release from muscle membranes was not dependent on medium [Ca2+] (from less than 10(-9) to approximately 10(-4) M). However, IP3 could activate the terminal cisternae Ca2+ channel in the bilayer when there was low Ca2+ (less than 10(-7) M). The data suggest that the ionic microenvironment around the Ca2+ channel may be different for observing the two phosphoinositide actions.     

Inositol 1,4,5-trisphosphate is not effective in releasing calcium from skeletal sarcoplasmic reticulum microsomes

Regulation of many cell systems has been shown to be mediated by Inositol 1,4,5-trisphosphate which causes a release of calcium from intracellular sites. We have shown that release of Ca2+ from sarcoplasmic reticulum microsomes was not stimulated by IP3. The phorbol ester, TPA, also had no effect on Ca2+ release or Ca2+ ATPase activity. Thus, it is unlikely that the breakdown of polyphosphatidylinositides serves as a second messenger to mediate release of Ca2+ in skeletal muscle.     

Dynamic regulation of intracellular calcium signals through calcium release channels

After the seminal work of Ebashi and coworkers which established the essential role of the intracellular Ca2+ concentration ([Ca2+]i) in the regulation of skeletal muscle contraction, we have witnessed an explosive elongation of the list of cell functions that are controlled by the [Ca2+]i. In numerous instances, release of intracellular Ca2+ stores plays important roles in Ca2+ signalling which displays significant variation in spatio-temporal pattern. There are two families of Ca2+ release channels, ryanodine receptors and inositol 1,4,5-trisphosphate (IP3) receptors. These Ca2+ release channels are structurally and functionally similar. In particular, the activity of both types of channels is regulated by the [Ca2+]i. The [Ca2+]i dependence of the Ca2+ release channel activity provides both types of channels with properties of a Ca2+ signal amplifier. This function of the ryanodine receptor is important in striated muscle excitation-contraction coupling, whereas that of the IP3 receptor seems to be the basis of the generation of Ca2+ waves. Thus the wide variety of Ca2+ signalling patterns seem to be critically dependent on the [Ca2+]i dependence of the Ca2+ release channels.     

Ca2+ release by inositol-trisphosphorothioate in isolated triads of rabbit skeletal muscle.

The effectiveness of the nonmetabolizable second messenger analogue DL-myo-inositol 1,4,5-trisphosphorothioate (IPS3) described by Cooke, A. M., R. Gigg, and B. V. L. Potter, (1987b. Jour. Chem. Soc. Chem. Commun. 1525-1526.) was examined in triads purified from rabbit skeletal muscle. A Ca2+ electrode uptake-release assay was used to determine the size and sensitivity of the IPS3-releasable pool of Ca2+ in isolated triads. Uptake was initiated by 1 mM MgATP, pCa 5.8, pH 7.5 Release was initiated when the free Ca2+ had lowered to pCa approximately 7. We found that 5-25 microM myo-inositol 1,4,5-trisphosphate (IP3), and separately IPS3, consistently released 5-20% of the Ca2+ pool actively loaded into triads. Single channel recording was used to determine if ryanodine receptor Ca2+ release channels were affected by IPS3 at the same myoplasmic Ca2+ and IPS3 concentrations. Open probability of ryanodine receptor Ca2+ release channels was monitored in triads fused to bilayers over long periods (200 s) in the absence and following addition of 30 microM IPS3 to the same channel. At myoplasmic pCa approximately 7, IPS3 had no effect in the absence of MgATP (Po = 0.0094 +/- 0.001 in control and Po = 0.01 +/- 0.006 after IPS3) and slightly increased activity in the presence of 1 mM MgATP (Po = 0.024 +/- 0.03 in control and Po = 0.05 +/- 0.03 after IPS3). Equally small effects were observed at higher myoplasmic Ca2+. The onset of channel activation by IPS3 or IP3 was slow, on the time scale 20-60 s. We suggest that in isolated triads of rabbit skeletal muscle, IP3-induced release of stored Ca2+ is probably not mediated by the opening of Ca2+ release channels.     

Functional studies of Ca2+ channels from plasmalemma and sarcoplasmic reticulum membranes in muscle cells

Physiological and biochemical studies (channel characteristics, intracellular Ca2+ determinations and, channel purification, cloning and expression) of the different components involved in the regulation of intercellular Ca2+ have provided new information about their specific role. Recent information favors a major role for plasmalemma Ca2+ channels in E-C coupling of cardiac muscle, while a major role for sarcoplasmic reticulum Ca2+ release channels (ryanodine receptors) is proposed for E-C coupling of skeletal muscle. In smooth muscle, both plasmalemma and sarcoplasmic reticulum (IP3 receptors) Ca2+ channels are involved in E-C coupling. These studies will be comparatively discussed for skeletal, cardiac and smooth muscle cells.     

The brain ryanodine receptor: a caffeine-sensitive calcium release channel.

The release of stored Ca2+ from intracellular pools triggers a variety of important neuronal processes. Physiological and pharmacological evidence has indicated the presence of caffeine-sensitive intracellular pools that are distinct from the well-characterized inositol 1,4,5,-trisphosphate (IP3)-gated pools. Here we report that the brain ryanodine receptor functions as a caffeine- and ryanodine-sensitive Ca2+ release channel that is distinct from the brain IP3 receptor. The brain ryanodine receptor has been purified 6700-fold with no change in [3H]ryanodine binding affinity and shown to be a homotetramer composed of an approximately 500 kd protein subunit, which is identified by anti-peptide antibodies against the skeletal and cardiac muscle ryanodine receptors. Our results demonstrate that the brain ryanodine receptor functions as a caffeine-sensitive Ca2+ release channel and thus is the likely gating mechanism for intracellular caffeine-sensitive Ca2+ pools in neurons.     

Calciosome, a sarcoplasmic reticulum-like organelle involved in intracellular Ca2+-handling by non-muscle cells: studies in human neutrophils and HL-60 cells

Calciosomes are intracellular organelles in HL-60 cells, neutrophils and various other cell types, characterized by their content of a Ca2+-binding protein that is biochemically and immunologically similar to calsequestrin (CS) from muscle cells. In subcellular fractionation studies the CS-like protein copurifies with functional markers of the inositol 1,4,5-trisphosphate (IP3) releasable Ca2+-store. These markers (ATP-dependent Ca2+-uptake and IP3-induced Ca2+-release) show a subcellular distribution which is clearly distinct from the endoplasmic reticulum and other organelles. In morphological studies, antibodies against rabbit skeletal muscle CS protein specifically stained hitherto unrecognized vesicles with a diameter between 50 and 250 nm. Thus both, biochemical and morphological studies indicate that the calsequestrin containing intracellular Ca2+-store, now referred to as the calciosome, is distinct from other known organelles such as endoplasmic reticulum. Calciosomes are likely to play an important role in intracellular Ca2+-homeostasis. They are possibly the intracellular target of inositol 1,4,5-trisphosphate and thus the source of Ca2+ that is redistributed into the cytosol following surface receptor activation in non-muscle cells.     

Temperature and nucleotide dependence of calcium release by myo-inositol 1,4,5-trisphosphate in cultured vascular smooth muscle cells

Inositol 1,4,5-trisphosphate (IP3) rapidly increased 45Ca2+ efflux from a nonmitochondrial organelle in cultured vascular smooth muscle cells that were permeabilized with saponin. A nucleotide, preferably ATP, was essential for IP3-evoked 45Ca2+ release. Two nonhydrolyzable ATP analogues satisfied the nucleotide requirement for IP3-evoked 45Ca2+ release. IP3 strongly stimulated 45Ca2+ efflux at low temperatures (1 to 15 degrees C). Decreasing the temperature from 37 to 4 degrees C inhibited the rate of IP3-stimulated efflux by only about 33%. The failure of such low temperatures to strongly inhibit IP3-induced 45Ca2+ efflux suggests that IP3 activated a Ca2+ channel, rather than a carrier, by a ligand-binding, rather than a metabolic, reaction.     

Systemic ablation of RyR3 alters Ca2+ spark signaling in adult skeletal muscle

Ca2+ sparks are localized intracellular Ca2+ release events from the sarcoplasmic reticulum in muscle cells that result from synchronized opening of ryanodine receptors (RyR). In mammalian skeletal muscle, RyR1 is the predominant isoform present in adult skeletal fibers, while some RyR3 is expressed during development. Functional studies have revealed a differential role for RyR1 and RyR3 in the overall Ca2+ signaling in skeletal muscle, but the contribution of these two isoforms to Ca2+ sparks in adult mammalian skeletal muscle has not been fully examined. When enzyme-disassociated, individual adult skeletal muscle fibers are exposed to an osmotic shock, the resting fiber converts from a quiescent to a highly active Ca2+ release state where Ca2+ sparks appear proximal to the sarcolemmal membrane. These osmotic shock-induced Ca2+ sparks occur in ryr3(-/-) muscle with a spatial distribution similar to that seen in wild type muscle. Kinetic analysis reveals that systemic ablation of RyR3 results in significant changes to the initiation, duration and amplitude of individual Ca2+ sparks in muscle fibers. These changes may reflect the adaptation of the muscle Ca2+ signaling or contractile machinery due to the loss of RyR3 expression in distal tissues, as biochemical assays identify significant changes in expression of myosin heavy chain protein in ryr3(-/-) muscle.     

Expression and Cellular Localization of a Modified Type 1 Ryanodine Receptor and L-Type Channel Proteins in Non-Muscle Cells

Functional and molecular biological evidence exists for the expression of ryanodine receptors in non-muscle cells. In the present study, RT-PCR and 5'-rapid amplification of cDNA 5'-end (5'-RACE analysis) provided evidence for the presence of a type 1 ryanodine receptor/Ca2+ channel (RyR1) in diverse cell types. In parotid gland-derived 3-9 (epithelial) cells, the 3'-end 1589 nucleotide sequence for a rat RyR shared 99% homology with rat brain RyR1. Expression of this RyR mRNA sequence in exocrine acinar cells, endocrine cells, and liver in addition to skeletal muscle and cardiac muscle, suggests wide tissue distribution of the RyR1. Positive identification of a 5'-end sequence was made for RyR1 mRNA in rat skeletal muscle and brain, but not in parotid cells, pancreatic islets, insulinoma cells, or liver. These data suggest that a modified RyR1 is present in exocrine and endocrine cells, and liver. Western blot analysis showed L-type Ca2+ channel-related proteins in parotid acinar cells, which were of comparable size to those identified in skeletal and cardiac muscle, and in brain. Immunocytochemistry carried out on intact parotid acini demonstrated that the dihydropyridine receptor was preferentially co-localized with the IP3 receptor in the apical membranes. From these data we conclude that certain non-muscle cells express a modified RyR1 and L-type Ca2+ channel proteins. These receptor/channels may play a role in Ca2+ signaling involving store-operated Ca2+ influx via receptor-mediated channels.     

Possible link of different slow calcium signals generated by membrane potential and hormones to differential gene expression in cultured muscle cells

The study of fluorescent calcium signals from cultured rat myotubes has provided interesting results in the past few years. Both K+ depolarization and tetanic electrical stimulation were shown to produce slow Ca2+ signals, unrelated to contraction and associated to regulation of gene expression in cultured rat myotubes. We studied the effect of IGF-I, insulin and testosterone on intracellular Ca2+ in cultured muscle cells. Insulin produced a fast (< 1 s) and transient [Ca2+] increase lasting less than 10 s. IGF-I induced a transient [Ca2+] increase, reaching a fluorescence peak 6 s after stimulus, to return to basal values after 60 s. Testosterone induced delayed (35 s) and long lasting (100-200 s) signals, frequently associated with oscillations. IGF-I, testosterone and electrical stimulation-induced Ca2+ signals were shown to be dependent on IP3 production. All of these Ca2+ signals were blocked by inhibitors of the IP3 pathway. On the other hand, insulin-induced Ca2+ increase was dependent on ryanodine receptors and blocked by either nifedipine or ryanodine. The different intracellular Ca2+ patterns produced by electrical stimulation, testosterone, IGF-I and insulin, may help to understand the role of intracellular calcium kinetics in the regulation of gene expression by various stimuli in skeletal muscle cells.     

Chloride-dependent sarcoplasmic reticulum Ca2+ release correlates with increased Ca2+ activation of ryanodine receptors.

The mechanism by which chloride increases sarcoplasmic reticulum (SR) Ca2+ permeability was investigated. In the presence of 3 microM Ca2+, Ca2+ release from 45Ca(2+)-loaded SR vesicles prepared from procine skeletal muscle was increased approximately 4-fold when the media contained 150 mM chloride versus 150 mM propionate, whereas in the presence of 30 nM Ca2+, Ca2+ release was similar in the chloride- and the propionate-containing media. Ca(2+)-activated [3H]ryanodine binding to skeletal muscle SR was also increased (2- to 10-fold) in media in which propionate or other organic anions were replaced with chloride; however, chloride had little or no effect on cardiac muscle SR 45Ca2+ release or [3H]ryanodine binding. Ca(2+)-activated [3H]ryanodine binding was increased approximately 4.5-fold after reconstitution of skeletal muscle RYR protein into liposomes, and [3H]ryanodine binding to reconstituted RYR protein was similar in chloride- and propionate-containing media, suggesting that the sensitivity of the RYR protein to changes in the anionic composition of the media may be diminished upon reconstitution. Together, our results demonstrate a close correlation between chloride-dependent increases in SR Ca2+ permeability and increased Ca2+ activation of skeletal muscle RYR channels. We postulate that media containing supraphysiological concentrations of chloride or other inorganic anions may enhance skeletal muscle RYR activity by favoring a conformational state of the channel that exhibits increased activation by Ca2+ in comparison to the Ca2+ activation exhibited by this channel in native membranes in the presence of physiological chloride (< or = 10 mM). Transitions to this putative Ca(2+)-activatable state may thus provide a mechanism for controlling the activation of RYR channels in skeletal muscle.     

Homer modulates NFAT-dependent signaling during muscle differentiation

While changes in intracellular calcium are well known to influence muscle contraction through excitation contraction coupling, little is understood of the calcium signaling events regulating gene expression through the calcineurin/NFAT pathway in muscle. Here, we demonstrate that Ca(+2) released via the inositol trisphosphate receptor (IP3R) increases nuclear entry of NFAT in undifferentiated skeletal myoblasts, but the IP3R Ca(+2) pool in differentiated myotubes promotes nuclear exit of NFAT despite a comparable quantitative change in [Ca(+2)]i. In contrast, Ca(+2) released via ryanodine receptors (RYR) increases NFAT nuclear entry in myotubes. The scaffolding protein Homer, known to interact with both IP3R and RYR, is expressed as part of the myogenic differentiation program and enhances NFAT-dependent signaling by increasing RYR Ca(+2) release. These results demonstrate that differentiated skeletal myotubes employ discrete pools of intracellular calcium to restrain (IP3R pool) or activate (RYR pool) NFAT-dependent signaling, in a manner distinct from undifferentiated myoblasts. The selective expression of Homer proteins contributes to these differentiation-dependent features of calcium signaling.