Depolarization-induced calcium release from sarcoplasmic reticulum fragments. II. Release of calcium incorporated with ATP.

Ca2& incorporated in vesicles of sarcoplasmic reticulum fragments (SRF) by diffusion could be released rapidly by changing the ionic environment, by dilution from methanesulfonate (MS) to chloride. This ion exchange is considered to make the membrane potential of SRF inside-negative. Much faster release of Ca2t was also observed upon osmotic change from high to low. These responses were very similar to the Ca2& release from SRF after take up using ATP, but the release rate was slow in the case of anion exchnage. The behavior of K&, Na&, sucrose, and inulin incorporated in SRF was followed upon similar treatment. These ions and nolecules were not released upon ion exchange, but were immediately released by osomtic treatment. Therefore, the Ca& release upon anion exchange was not due to the bursting of SRF, but to a direct effect such as a membrane potential change of the SRF. The behavior of anion such as C1- and propionate could not followed by the same method because of the large permability of these anions. It was also shown that Ca& release upon ion exchange was not a direct effect of pH change. Liver microsomes did not show Ca& release upon the same treatment as SRF.     

Kinetic studies of calcium release from sarcoplasmic reticulum in vitro

Release of Ca2+ from a heavy fraction of rabbit skeletal muscle sarcoplasmic reticulum was triggered by several different methods: (a) increasing extravesicular [Ca2+] [( CaO2+] from about 0.1 microM to 10 microM), (b), adding caffeine, (c) adding quercetin, and (d) substituting a solution containing equimolar choline+ for K+-containing solution (depolarization-induced Ca2+ release). The maximal rate of Ca2+ release triggered by caffeine or quercetin in the presence of 12.5 microM [CaO2+] (21-25 nmol of Ca2+/mg/s) is similar to that of the depolarization-induced Ca2+ release (19 nmol of Ca2+/mg/s), as determined by stopped flow spectrometry of changes in [CaO2+] with arsenazo III. The release is transient and all of the released Ca2+ is reaccumulated. The rates of Ca2+ release triggered by caffeine, quercetin, or membrane depolarization sharply decrease at high [CaO2+], suggesting a negative feedback effect of the released Ca2+. Inhibition of the release pathway allows the sarcoplasmic reticulum to reaccumulate Ca2+. The rate of Ca2+ release triggered by caffeine or quercetin, but not that triggered by membrane depolarization, is also reduced upon decreasing [CaO2+] to the submicromolar range. Passive efflux of intravesicular Ca2+ in solutions containing lower [CaO2+] in the absence of Mg.ATP is attenuated at about the same time (congruent to 1 min) regardless of the amounts of Ca2+ released, indicating that the opened Ca2+ channels close spontaneously. These results suggest that kinetically identical channels are responsible for Ca2+ release independent of the methods of triggering and this in vitro release is consistent with the physiological mechanism both in terms of the rapidity and the reversibility of Ca2+ release.     

Utilization of X-537A to distinguish between intravesicular and membrane-bound calcium ions in sarcoplasmic reticulum.

The Ca2+ ionophore X-537A is employed as a tool to distinguish between intravesicular Ca2+ and surface membrane-bound Ca2+ in sarcoplasmic reticulum isolated from rabbit skeletal muscle. When sarcoplasmic reticulum is incubated in 20 mM Ca2+ in the absence of ATP, 10-12 h are necessary for measurable amount of Ca2+ to penetrate into the vesicular space, as determined by the fact that X-537A releases Ca2+ from 'loaded' vesicles only after this period of incubation. A fraction of Ca2+ of 50-60 nmol/mg protein, rapidly taken up by sarcoplasmic reticulum, exchanges with Mg2+ and K+ in the medium and is readily released by ethyleneglycol-bis-(beta-aminoethyl ether)-N,N'-tetraacetic acid, but it is not released by X-537A. The slow-penetrating fraction of Ca2+ (30-40 nmol/mg protein) is rapidly released X-537A. The results indicate that most of the Ca2+ retained by sarcoplasmic reticulum under conditions of passive uptake is bound to the external side of the membrane. The fraction of Ca2+ that slowly penetrates the vesicles remains essentially free inside the vesicles and only a small part is bound to the internal side of the membrane.     

Lack of effects of calcium X calmodulin-dependent phosphorylation on Ca2+ release from cardiac sarcoplasmic reticulum

Canine cardiac sarcoplasmic reticulum is phosphorylated by an endogenous calcium X calmodulin-dependent protein kinase and phosphorylation occurs mainly on a 27 kDa proteolipid, called phospholamban. To determine whether this phosphorylation has any effect on Ca2+ release, sarcoplasmic reticulum vesicles were phosphorylated by the calcium X calmodulin-dependent protein kinase, while non-phosphorylated vesicles were preincubated under identical conditions but in the absence of ATP to avoid phosphorylation. Both non-phosphorylated and phosphorylated vesicles were centrifuged to remove calmodulin, and subsequently used for Ca2+ release studies. Calcium loading was carried out either by the active calcium pump or by incubation with high (5 mM) calcium for longer periods. Phosphorylation of sarcoplasmic reticulum by calcium X calmodulin-dependent protein kinase had no appreciable effect on the initial rates of Ca2+ released from cardiac sarcoplasmic reticulum vesicles loaded under passive conditions and on the apparent 45Ca2+-40Ca2+ exchange from cardiac sarcoplasmic reticulum vesicles loaded under active conditions. Thus, it appears that calcium X calmodulin-dependent protein kinase mediated phosphorylation of cardiac sarcoplasmic reticulum is not involved in the regulation of Ca2+ release and 45Ca2+-40Ca2+ exchange.     

Mechanisms involved in the cellular calcium homeostasis in vascular smooth muscle: calcium pumps

The regulation of cytosolic Ca2+ homeostasis is essential for cells, and particularly for vascular smooth muscle cells. In this regulation, there is a participation of different factors and mechanisms situated at different levels in the cell, among them Ca2+ pumps play an important role. Thus, Ca2+ pump, to extrude Ca2+; Na+/Ca2+ exchanger; and different Ca2+ channels for Ca2+ entry are placed in the plasma membrane. In addition, the inner and outer surfaces of the plasmalemma possess the ability to bind Ca2+ that can be released by different agonists. The sarcoplasmic reticulum has an active role in this Ca2+ regulation; its membrane has a Ca2+ pump that facilitates luminal Ca2+ accumulation, thus reducing the cytosolic free Ca2+ concentration. This pump can be inhibited by different agents. Physiologically, its activity is regulated by the protein phospholamban; thus, when it is in its unphosphorylated state such a Ca2+ pump is inhibited. The sarcoplasmic reticulum membrane also possesses receptors for 1,4,5-inositol trisphosphate and ryanodine, which upon activation facilitates Ca2+ release from this store. The sarcoplasmic reticulum and the plasmalemma form the superficial buffer barrier that is considered as an effective barrier for Ca2+ influx. The cytosol possesses different proteins and several inorganic compounds with a Ca2+ buffering capacity. The hypothesis of capacitative Ca2+ entry into smooth muscle across the plasma membrane after intracellular store depletion and its mechanisms of inhibition and activation is also commented.     

Charge changes in sarcoplasmic reticulum and Ca2+-ATPase induced by calcium binding and release: a study using lipophilic ions

Changes in the charge of sarcoplasmic reticulum (SR) vesicles are studied using lipophilic ions, which are adsorbed by the membrane phase. Upon addition of MgATP, phenyldicarbaundecaborane (PCB-) and tetraphenylboron (TPB-) are taken up by the SR vesicles, while tetraphenylphosphonium (TPP+) is released into the water phase. The PCB- uptake occurs as well under conditions when SR membrane is shunted by high Cl- concentration. MgATP induces minor additional binding of PCB- in the presence of oxalate and it is followed by release of the lipophilic anion from the vesicles. EGTA partly reverses the ATP effect, and calcium ionophore A23187 plus EGTA reverses it completely. Vesicles that were preliminarily loaded by Ca2+ demonstrated higher passive and lower ATP-dependent PCB- binding. Activation of isolated Ca2+-ATPase in the presence of 0.1 mM EGTA results in PCB- release into the medium and additional TPP+ binding to the enzyme. We suggest that the redistribution of the lipophilic ions between the water phase and SR membrane reflects charge changes in Ca2+-binding sites inside both SR vesicles and Ca2+-ATPase molecules in the course of Ca2+ translocation.     

Antioxidant-induced release of calcium in biological membranes

The effect of synthetic (BHT, 2,2,5,7,8-pentamethyl-6-hydroxychroman) and natural (alpha-tocopherol) antioxidants on Ca++-transporting systems was compared in platelets, brain synaptosomes, and skeletal muscle sarcoplasmic reticulum. It was shown that synthetic antioxidants, in contrast to alpha-tocopherol, induced Ca++-release manifested in platelet aggregation, stimulation of 5-hydroxytryptamine release by synaptosomes, synaptosome depolarization and inhibition of Ca++-transport and Ca++-ATPase activity in the sarcoplasmic reticulum. The disturbances of Ca++-homeostasis induced by synthetic antioxidants are considered as molecular mechanisms of complications encountered upon their application.     

Characterization of "depolarization"-induced calcium release from sarcoplasmic reticulum in vitro with the use of membrane potential probe.

In the triad, the complex of transverse (T) tubule and sarcoplasmic reticulum (SR) Ca2+ release is induced from SR by mediation of the T-tubule. We report here evidence that this Ca2+ release is produced by depolarization of the T-tubule moiety. Thus, we found that the amount of [14C]SCN- taken up by T-tubules and triads (but not that by SR) increased upon incubation with (K, Na) gluconate, Mg ATP, indicating that the T-tubule was polarized making the lumenal side (equivalent to the extracellular side of an intact muscle fiber) more positive. Upon mixing with choline chloride, the procedure to induce Ca2+ release, [14C]SCN- uptake decreased, indicating that the T-tubule became depolarized. Activation of the T-tubule polarization by Na+ and prevention of it by digoxin [inhibitor of the (Na+, K+) pump], respectively, led to activation and inhibition of choline chloride-induced SR Ca2+ release.     

Inhibitors of Ca2+ release from the isolated sarcoplasmic reticulum. II. The effects of dantrolene on Ca2+ release induced by caffeine, Ca2+ and depolarization

The effects of dantrolene, which is a known muscle relaxant, on Ca2+ release from the isolated sarcoplasmic reticulum induced by several different methods [1) addition of caffeine, (2) Ca2+ jump, and (3) membrane-depolarization produced by choline chloride replacement of potassium gluconate) were investigated. Dantrolene inhibited caffeine-induced Ca2+ release with C1/2 = 2.5 microM, whereas there was no effect on Ca2+ release induced by a Ca2+ jump. The amount of Ca2+ released by depolarization was reduced if Ca2+ release was triggered in an earlier phase of the steady state of Ca2+ uptake (time elapsed between the addition of ATP and the triggering of Ca2+ release, tATP less than 4 min); while, if triggered in a latter phase (tATP greater than 4 min) dantrolene enhanced depolarization-induced Ca2+ release. C1/2 for the inhibition and that for enhancement of depolarization-induced Ca2+ release were 1.0 and 0.3 microM, respectively. These results suggest that dantrolene affects several different steps of the mechanism by which Ca2+ release is triggered. The sarcoplasmic reticulum and T-tubule membrane fractions had 7.9 nmol dantrolene-binding sites/mg (Kassoc = 1.0 X 10(5) M-1) and 21.0 nmol/mg (Kassoc = 1.1 X 10(5) M-1), respectively. The time-course of dantrolene binding to sarcoplasmic reticulum was monophasic, while that to T-tubules was biphasic.     

Rapid filtration studies of Ca2+-induced Ca2+ release from skeletal sarcoplasmic reticulum. Role of monovalent ions

We have developed a rapid filtration technique for the measurement of Ca2+ release from isolated sarcoplasmic reticulum vesicles. Using this technique, we have studied the Ca2+-induced Ca2+ release of sarcoplasmic reticulum vesicles from rabbit skeletal muscle passively loaded with 5 mM Ca2+. The effect of known effectors (adenine nucleotides and caffeine) and inhibitors (Mg2+ and ruthenium red) of this release were investigated. In a medium composed of 100 mM KCl buffered at pH 6.8 with 20 mM K/3-(N-morpholino)propanesulfonic acid the Ca2+ release rate was maximal (500 nmol of Ca2+ released.(mg of protein)-1.s-1) at 1 micron external Ca2+ and 5 mM ATP. We also observed a rapid Ca2+ release induced by micromolar Ag+ in the presence of ATP (at 1 nM Ca2+). The Ag+-induced Ca2+ release was totally inhibited by 5 micron ruthenium red. We have also investigated the effect of monovalent ions on the Ca2+ release elicited by Ca2+ or Ag+. We show that the Ca2+ release rate: 1) was dependent upon the presence of K+ or Na+ in the release medium and 2) was influenced by a K+ gradient created across the sarcoplasmic reticulum membrane. These results directly support the idea of the involvement of an influx of K+ (through K+ channels) during the Ca2+ release and allow to reconsider a possible influence of the membrane potential of the sarcoplasmic reticulum on the Ca2+ release.     

Inhibitors of Ca2+ release from the isolated sarcoplasmic reticulum. I. Ca2+ channel blockers

The effects of Ruthenium red and tetracaine, which inhibit Ca2+-induced Ca2+ release from the isolated sarcoplasmic reticulum (e.g., Ohnishi, S.T. (1979) J. Biochem. (Tokyo) 86, 1147-1150), on several types of Ca2+ release in vitro were investigated. Ca2+ release was triggered by several methods: (1) addition of quercetin or caffeine, (2) Ca2+ jump, and (3) replacement of potassium gluconate with choline chloride to produce membrane depolarization. The time-course of Ca2+ release was monitored using stopped-flow spectrophotometry and arsenazo III as a Ca2+ indicator. Ruthenium red inhibited all of these types of Ca2+ release with the same concentration for half-inhibition C1/2 = 0.08-0.10 microM. Similarly, tetracaine inhibited these types of Ca2+ release with C1/2 = 0.07-0.11 mM. Procaine also inhibits both types of Ca2+ release induced by method 2 and 3 with C1/2 = 0.67-1.00 mM. These results suggest that Ruthenium red, tetracaine and procaine interfere with a common mechanism of the different types of Ca2+ release. On the basis of several pieces of evidence we propose that Ruthenium red and tetracaine block the Ca2+ channel of sarcoplasmic reticulum.     

Altered stored calcium release in skeletal myotubes deficient of triadin and junctin

Triadin and junctin are integral sarcoplasmic reticulum membrane proteins that form a macromolecular complex with the skeletal muscle ryanodine receptor (RyR1) but their roles in skeletal muscle calcium homeostasis remain incompletely understood. Here we report that delivery of siRNAs specific for triadin or junctin into C2C12 skeletal myoblasts reduced the expression of triadin and junctin in 8-day-old myotubes by 80 and 100%, respectively. Knocking down either triadin or junctin in these cells reduced Ca2+ release induced by depolarization (10mM KCl) by 20-25%. Unlike triadin knockdown myotubes, junctin knockdown and junctin/triadin double knockdown myotubes also had reduced Ca2+ release induced by 400 microM 4-chloro-m-cresol, 10mM caffeine, 400 microM UTP, or 1 microM thapsigargin. Thus, knocking down junctin compromised the Ca2+ stores in the sarcoplasmic reticulum of these cells. Our subsequent studies showed that in junctin knockdown myotubes at least two sarcoplasmic reticulum proteins (RyR1 and skeletal muscle calsequestrin) were down-regulated while these proteins' mRNA expression was not affected. The results suggest that triadin has a role in facilitating KCl depolarization-induced Ca2+ release in contrast to junctin which has a role in maintaining sarcoplasmic reticulum Ca2+ store size in C2C12 myotubes.     

Characterization of the tetraphenylboron-induced calcium release from skeletal sarcoplasmic reticulum

Release of Ca2+ from skeletal sarcoplasmic reticulum vesicles was studied by the spectrophotometric stopped-flow technique using tetraphenylboron as a releasing agent. The extent of Ca2+ release shows a sigmoidal response, with respect to the tetraphenylboron concentration, being dependent on Ca2+ preloading and Ca2+-ATPase activity, since these experiments were performed on actively loaded vesicles. The release process has a rapid component with an apparent rate constant of 6-8 s-1, showing a linear relationship between the rapid rate of Ca2+ release and the Ca2+ content of the vesicles. The release is not mediated by the reversal of the Ca2+ pump. Since the amphipathic anion tetraphenylboron was unable to elicit a Ca2+-release response when added to a preparation of sarcoplasmic reticulum phospholipid vesicles, it is suggested that there may be an interaction with some membrane protein(s) at the hydrophobic/hydrophilic interface leading to the opening of some specific Ca2+-release pathway.     

Effect of pH on calcium accumulation and release by isolated fragments of cardiac and skeletal muscle sarcoplasmic reticulum.

The ability of a sudden increase in pH to initiate a release of calcium from isolated skeletal and cardiac muscle sarcoplasmic reticulum following calcium accumulation in the absence of a precipitating anion (calcium binding) is described. In skeletal sarcoplasmic reticulum a sudden increase in pH caused a rapid release of accumulated calcium. In cardiac sarcoplasmic reticulum a sudden increase in pH before the calcium binding process was complete caused the release of a small amount of calcium at a relatively slow rate. A sudden change in pH after the completion of calcium binding failed to trigger a release of calcium. The effect of pH on oxalate supported calcium uptake and on unidirectional calcium efflux rate by cardiac sarcoplasmic reticulum was also studied. Both the rate of calcium uptake and of unidirectional calcium efflux increased as the pH was raised from 6.4 to 7.2, reflecting an increased permeability of the sarcoplasmic reticulum membrane to calcium. These results indicate that in cardiac muscle a sudden increase in pH is unlikely to be the in vivo signal for calcium release from the sarcoplasmic reticulum. However, the effect of pH on calcium uptake and efflux by cardiac sarcoplasmic reticulum may contribute to the negative inotropic effect of an acidosis on the heart.     

Role of sarcoplasmic reticulum phospholipids in calcium ion binding activity

The relationship between sarcoplasmic reticulum phospholipid and Ca(2+) binding by sarcoplasmic reticulum membranes was explored. Ca(2+) bound in the absence of ATP was defined as "ATP-independent Ca(2+) binding," and the additional amount of Ca(2+) bound in the presence of ATP was defined as "ATP-dependent Ca(2+) binding." The latter was found to be very sensitive to the loss of sarcoplasmic reticulum phospholipid; the amount of Ca(2+) bound was reduced when as little as 3% of the phospholipid was destroyed by phospholipase C. Further destruction of membrane phospholipid up to a 40% loss caused little or no further reduction of this Ca(2+) binding. However, when the destruction of phospholipid exceeded 40%, further loss of this Ca(2+) binding occurred, and there was an almost complete loss of this function when more than 60% of the sarcoplasmic reticulum phospholipid was destroyed.     

Sidedness of K+ activation of calcium transport in the reconstituted sarcoplasmic reticulum calcium pump

Sidedness of the effect of K+ on Ca transport by the sarcoplasmic reticulum Ca pump reconstituted into soybean phospholipid vesicles was investigated. The reconstituted vesicles which sustained a high rate of Ca transport even in the absence of Ca-precipitating anions exhibited low passive permeabilities to 42K+, 86Rb+, or 45Ca2+. Evidence was presented that K+ activated the Ca pump on the external surface of the vesicles and that it was not taken up by the vesicles during the pump activity. In the presence of high externally added K+, the reconstituted vesicles preloaded with K+ exhibited a significantly higher Ca transport activity than the vesicles preloaded with Tris+ but not the ones preloaded with Li+. Ca transport by the K+-loaded vesicles was accompanied by a small amount of K+ efflux, which corresponded to about 20% of the amount of Ca+ taken up. Since the intravesicular K+ did not affect the turnover of the ADP-insensitive component (E2P) of the phosphoenzyme intermediate formed during the pump cycle, it was concluded that the intravesicular K+ stimulated the Ca pump activity indirectly by compensating the charge imbalance caused by the electrogenic Ca2+ movement. These results thus indicate that K+ activates the Ca pump only on the cytoplasmic side of the sarcoplasmic reticulum membrane, but it is not obligately transported across the membrane under conditions where K+ fully activates the Ca pump.     

The effect of calcium ion transport ATPase upon the passive calcium ion permeability of phospholipid vesicles.

The uptake and release of Ca2+ by sarcoplasmic reticulum fragments and reconstituted ATPase vesicles was measured by a stopped-flow fluorescence method using chlortetracycline as Ca2+ indicator. Incorporation of the Ca2+ transport ATPase into phospholipid bilayers of widely different fatty acid composition increases their passive permeability to Ca2+ by several orders of magnitude. Therefore in addition to participating in active Ca2+ transport, the (Mg2+ + Ca2+)-activated ATPase also forms hydrophilic channels across the membrane. The relative insensitivity of the permeability effect of ATPase to changes in the fatty acid composition of the membrane is in accord with the suggestion that the Ca2+ channels arise by protein-protein interaction between four ATPase molecules. The reversible formation of these channels may have physiological significance in the rapid Ca2+ release from the sarcoplasmic reticulum during activation of muscle.     

Measuring real-time sarcoplasmic reticulum calcium pumping in skinned muscle fibers

A method and a device for direct measurements of accumulation of calcium in the sarcoplasmic reticulum (SR) and its release from SR as a function of free Ca2+ in bath have been developed. About 30% of the volume inside muscle fibers of swimbladder of Opsanus tau is occupied by SR. A set of solutions was prepared for fiber dissection and making holes in outer membrane without destruction of membranes of the sarcoplasmic reticulum. Calcium was unloaded from SR using EGTA as a pCa buffer. Then solutions with 50-100 microM CaFURA2 or CabisFURA2 were used as pCa-buffer and fluorescent Ca-indicators for measurement of Ca exchange between a fiber with a volume of approximately 10 nl and a solution in the cuvette with a volume of 5 microl. An increase in fluorescence signified an increase in unbound FURA in the bath since Ca2+ pumped into the SR was removed from the bath. The slope represented the rate of Ca2+ uptake by the SR in the muscle fiber, the maximum being about 1.6 M/s per liter of solution in bath or 2.6 mM/s per liter of SR volume. In solutions without oxalate and Ruthenium Red, more Ca2+ was taken up by the SR, and oscillations of the bath free FURA level were often observed, which can be explained by calcium-induced calcium release.     

Activation of skinned muscle fibers by calcium and strontium ions

Intact and mechanically skinned skeletal muscle fibers of the crab Carcinus maenas have been used. The aim of the experiments was to determine the origin of the mechanical activity recorded in intact crab muscle fibers exhibiting an inward strontium current in strontium solution without calcium. To do so, the effect of strontium ions in inducing activation of contractile proteins and calcium release from the sarcoplasmic reticulum has been studied. The properties of the sarcoplasmic reticulum membrane towards strontium ions, i.e., the efficiency of the calcium ATPase towards strontium ions and the capability to release strontium ions have been investigated. Results show that the contractile proteins have a lower affinity for strontium than for calcium ions. However, the maximum bound strontium is identical to the maximum bound calcium. As for the sarcoplasmic reticulum, strontium ions can induce a calcium release and also can be taken up by the calcium ATPase and be released. We concluded that the mechanical activity in intact fibers bathed in a strontium medium has two origins: first, a direct and partial activation of the contractile proteins by strontium ions flowing through the calcium channel; second, a contractile proteins activation of calcium ions released by the sarcoplasmic reticulum by a "strontium-induced calcium release" mechanism.     

The effect of caffeine on calcium efflux and calcium translocation in skeletal and visceral muscle.

1. KCl-induced depolarization resulted in a large stimulation of the 45Ca efflux from both cockroach skeletal muscle and rat ileal smooth muscle. 2. Caffeine (10 mM) induced a large stimulation of 45Ca efflux from skeletal muscle, but a fall in the efflux from ileal muscle, especially if the efflux was previously stimulated by KCl depolarization. 3. Caffeine inhibited calcium uptake by skeletal muscle mitochondria and sarcoplasmic reticulum, was without effect on ileal muscle mitochondria, but significantly increased caclium binding by ileal muscle membrane vesicular preparations. 4. The induction of contractures and stimulation of 45Ca efflux in skeletal muscle by caffeine are clearly related to inhibition of intracellular calcium binding by the sarcoplasmic reticulum and mitochondria. 5. The relaxation of ileal muscle by caffeine and the inhibition of fibre calcium efflux correlate well with caffeine enhancement of intracellular calcium binding. These experiments suggest that the membrane vesicular compartment may be the main agency centrally involved in fibre calcium regulation in this muscle during the contraction-relaxation cycle.