Role of pentoxifylline in preventing radiation damage to epiphyseal growth plate chondrocytes.

Radiation therapy plays an important role as part of multimodality treatment for a number of childhood malignancies. The damaging effects of radiation on bone formation in children have been well documented. Recent work suggests that the postirradiation increase in cytosolic calcium is probably responsible for the deleterious effects of radiation on growth plate chondrocytes because it causes a specific suppression of the mitogen PTHrP. Using an in vitro model of avian growth plate chondrocytes, this study demonstrates that pentoxifylline is effective in increasing basal PTHrP mRNA levels and partially preventing the radiation-induced decrease in PTHrP mRNA. This effect of pentoxifylline is probably due to its ability to lower basal levels of cytosolic calcium and the radiation-induced increase in cytosolic calcium in chondrocytes. Pentoxifylline also prevented the radiation-induced decreases in [3H]thymidine uptake and BCL2 and PTHrP receptor mRNA levels in chondrocytes. The effects of pentoxifylline appear to be specific for the PTHrP signaling pathway because it did not alter basal TGFB mRNA levels or TGFB mRNA expression in irradiated chondrocytes. The results of the current study suggest that by decreasing basal cytosolic calcium levels and curtailing the radiation-induced increase in cytosolic calcium levels in chondrocytes, pentoxifylline is able to sustain PTHrP signaling in chondrocytes and maintains the proliferative signal that is necessary to prevent chondrocytes from undergoing apoptosis.     

Molecular properties of the red cell calcium pump: I. Effects of calmodulin,proteolytic digestion and drugs on the kinetics of active calcium uptake in inside-out red cell membrane vesicles

In calmodulin-stripped inside-out human red cell membrane vesicles /IOV/ ATP + Mg²⁺-dependent active calcium uptake is stimulated by the addition of calmodulin. Calmodulin increases the maximum calcium transport rate /V_max/, decreases K_Ca, and does not affect K_ATP of calcium uptake. The action of both membrane bound and external calmodulin is competitively inhibited by phenothiazines. Drugs reacting with SH groups of proteins reversibly inhibit calcium pumping by decreasing V_max and not affecting K_Ca and K_ATP. The relative magnitude of calmodulin stimulation of calcium transport is unaltered by SH reagents.Mild proteolytic digestion of IOVs stimulates active calcium uptake and mimics the effects of calmodulin on the kinetic parameters — that is converts the system to a “high calcium-affinity” state. Proteolysis eliminates calcium-dependent calmodulin binding to IOV membranes and any further stimulation of calcium uptake by calmodulin. Based on these results the presence of a calmodulin-binding regulatory subunit of the red cell calcium pump at the internal membrane surface is postulated.     

The effects of psychoactive agents on calcium uptake by preparations of rat brain mitochondria

The effects of chlorpromazine and other psychoactive agents on the uptake of calcium by partially purified preparations of mitochondria from rat brain were studied in vitro. Chlorpromazine at concentrations of about 0-1 ITIM caused a marked inhibition of mitochondrial calcium transport. Perphenazine also exhibited this action and was slightly more potent than chlorpromazine. Imipramine inhibited mitochondrial calcium uptake but higher concentrations were necessary than in experiments with chlorpromazine. The sulph-oxide of chlorpromazine did not inhibit calcium transport when tested at concentrations similar to those used with chlorpromazine. Up to concentrations of 20 mM, lithium ions did not influence mitochondrial calcium uptake.     

Polyamines Stimulate Mitochondrial Calcium Transport in Rat Brain

The effects of the polyamines spermine and spermidine on rat brain mitochondrial calcium transport were examined using a variety of techniques for measuring the kinetics of calcium uptake and the buffering capabilities of isolated mitochondria. Spermine both increased the rate of calcium accumulation and decreased the set-point to which isolated mitochondria buffer free calcium concentration. In the presence of physiological concentrations of sodium and magnesium, spermine lowered the extramitochondrial calcium level to approximately 0.3 microM, a value close to the resting intracellular calcium concentration. The effect of polyamines was concentration dependent, with a half-maximal effect of spermine observed at approximately 0.1-0.4 mM (respiratory substrate dependent), whereas spermidine was approximately 10 times less potent. Calcium transport by hippocampal mitochondria was stimulated markedly more by spermine than was calcium transport by mitochondria isolated from brainstem. The stimulatory effect of spermine was not due to an increase in the transport of respiratory substrates inside the mitochondria nor to an effect on the enzymes using these respiratory substrates. An examination of the effect of spermine on the kinetics of calcium uptake indicated that spermine increased calcium uptake maximally at low calcium concentrations. Beyond that level, the stimulatory effect of spermine decreases, and spermine can even inhibit calcium uptake. These results are in good agreement with previous reports on the effects of polyamines on calcium transport in mitochondria from peripheral tissue. They support the hypothesis that spermine increases the rate of calcium uptake by mitochondria by increasing the affinity of the uniporter for calcium.(ABSTRACT TRUNCATED AT 250 WORDS)     

p32, a novel binding partner of Mcl-1, positively regulates mitochondrial Ca uptake and apoptosis

Mcl-1 is a major anti-apoptotic Bcl-2 family protein. It is well known that Mcl-1 can interact with certain pro-apoptotic Bcl-2 family proteins in normal cells to neutralize their pro-apoptotic functions, thus prevent apoptosis. In addition, it was recently found that Mcl-1 can also inhibit mitochondrial calcium uptake. The detailed mechanism, however, is still not clear. Based on Yeast Two-Hybrid screening and co-immunoprecipitation, we identified a mitochondrial protein p32 (C1qbp) as a novel binding partner of Mcl-1. We found that p32 had a number of interesting properties: (1) p32 can positively regulate UV-induced apoptosis in HeLa cells. (2) Over-expressing p32 could significantly promote mitochondrial calcium uptake, while silencing p32 by siRNA suppressed it. (3) In p32 knockdown cells, Ruthenium Red treatment (an inhibitor of mitochondrial calcium uniporter) showed no further suppressive effect on mitochondrial calcium uptake. In addition, in Ruthenium Red treated cells, Mcl-1 also failed to suppress mitochondrial calcium uptake. Taken together, our findings suggest that p32 is part of the putative mitochondrial uniporter that facilitates mitochondrial calcium uptake. By binding to p32, Mcl-1 can interfere with the uniporter function, thus inhibit the mitochondrial Ca²⁺ uploading. This may provide a novel mechanism to explain the anti-apoptotic function of Mcl-1.     

Role of proteins in protection against radiation-induced damage in membranes

The effect of gamma irradiation on liposomes in the presence of a large number of commercially available proteins has been studied. Experiments were designed to demonstrate that the configuration of both acyl chain and cis C = C bonds created by lipid-protein associations are crucial in autocatalyzed radiation-induced lipid peroxidation. Raman spectroscopy was used to characterize these states. Raman spectra in the C-C stretching region show three prominent bands at 1064, 1090, and 1125 cm-1, assigned to trans, gauche, and trans C-C bonds, respectively. A single symmetrical C = C stretching band assigned to the cis isomer occurs at 1660 cm-1. The intensity ratios (I1064/I1090) and (I1660/I1440) are used as Raman probes to define the conformational states of acyl chains and C = C bonds, respectively. Our data show that the ratio (I1064/I1090) decreases in the presence of proteins, indicating that these proteins induce more gauche structures. Upon irradiation, the ratio (I1064/I1090) increases by about 30% in the absence of proteins and by about 15% in the presence of proteins. This shows that proteins retain the gauche structures in irradiated samples. The ratio (I1660/I1440) decreases in liposomes containing proteins, showing that proteins modify the configuration of cis C = C bonds. Upon irradiation, this ratio decreases by about 45-50% in samples without proteins and by about 10% in samples with proteins. These data show that proteins inhibit the radiation-induced configurational changes in the cis C = C bonds. The determination of radiation-induced peroxides (as malondialdehyde equivalents) in liposomes reveals that proteins inhibit the formation of peroxide products at low molar ratio and that the preventive capacity of different proteins is different. We conclude that proteins alter the conformation of both acyl chains and cis C = C bonds in liposomes and that these altered states are less sensitive to radiation-induced peroxidation.     

Effects of essential divalent metals on carcinogenicity and metabolism of nickel and cadmium

Interactions between the physiologically essential metals calcium, magnesium, and zinc and the carcinogenic metals nickel and cadmium were investigated to help elucidate the mechanisms of action of the carcinogenic metals. Bioassay studies revealed several significant findings, including: (1) the ability of magnesium and calcium to inhibit nickel-induced elevation of pulmonary adenoma incidence in strain A mice; (2) the ability of magnesium, but not of calcium, to prevent cadmium-induced subcutaneous sarcoma formation; and (3) the ability of magnesium, but not of calcium, to inhibit nickel-induced muscle tumor formation. Biochemical studies indicated a direct relationship between the antitumorigenic potential of magnesium and the capacity of this metal to: (1) inhibit nickel and cadmium uptake by the target tissues in vivo; (2) inhibit nickel-induced disturbances in DNA synthesis in vivo; (3) inhibit nuclear and cytosolic uptake of nickel by the target tissue cells in vivo; and (4) inhibit nickel and cadmium binding to DNA in vitro. Calcium, which in most cases did not prevent carcinogenesis, had no consistent influence on the uptake of carcinogenic metals or their biochemical effects in the target tissues. Magnesium and zinc, but not calcium, were also found to attenuate the acute toxic effects of nickel, indicating a possible correlation between prevention of acute effects and reduction in tumorigenicity. Zinc, which antagonizes cadmium tumorigenicity in the rat testis, was found to reduce markedly cadmium uptake into isolated testicular interstitial cells. Also, zinc was found to inhibit strongly cadmium binding to DNA in vitro.     

The effects of several ion channel blockers and calmodulin antagonists on fertilization-induced acid release and 45Ca2+ uptake in sea urchin eggs

The effects of calcium antagonists, diltiazem and verapamil, and calmodulin antagonists, chlorpromazine, N-(6-aminohexyl)-1-naphthalenesulfonamide hydrochloride (W-5) and N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide hydrochloride (W-7), were tested on two responses of the sea urchin egg to insemination: (1) H+ release; (2) Ca2+ uptake. It was found that calcium antagonists inhibited both processes, while calmodulin antagonists only inhibited H+ release but not Ca2+ uptake. Verapamil and diltiazem were effective to inhibit H+ release when added to the egg suspension up to 120 sec and W-7 was effective around 150 sec after insemination. Calcium antagonists became ineffective earlier than W-7 in inhibiting H+ release. A calmodulin-dependent step may thus occur linking the Ca2+ uptake and H+ release. 4,4'-Diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), an anion channel blocker, also inhibited both Ca2+ uptake and H+ release. This result suggests that an uptake of anion(s) occurs along with Ca2+ uptake.     

Dependence of calcium permeability of sarcoplasmic reticulum vesicles on external and internal calcium ion concentrations.

The ability of sarcoplasmic reticulum vesicles to retain calcium following ATP-supported calcium uptake in the presence of the calcium-precipitating anions oxalate and phosphate depends on Cao (calcium ion concentration outside the vesicles) and Cai (calcium ion concentration within the vesicles). Calcium efflux rates at any level of Cai are accelerated when Cao is increased. Higher Cao at the time that calcium uptake reactions reach steady state is associated with a spontaneous calcium release that reflects this effect of increased Cao. Increasing Cai at any level of Cao causes little or no acceleration of calcium efflux rate so that calcium permeability coefficients, estimated by dividing calcium efflux rates by Cai, the "driving force", are inversely proportional to Cai. Calcium permability coefficients thus correlate, as a first approximation, with the ratio Cai/Cao, decreasing 1000-fold as this ratio increases over a 3000-fold range (Cao = 0.1 to 3.3 muM, Cai =4 to 750 muM). Oscillations in both the calcium content of the vesicles and Cao are seen as calcium uptake reactions approach steady state, suggesting that calcium permeability undergoes time-dependent variations. Sudden reduction of Cao to levels that markedly inhibit calcium influx via the calcium pump unmasks a calcium efflux that decreases slowly over 60 to 90 s.The maximal calcium permeability observed in the present study would allow the calcium efflux rate from the sarcoplasmic reticulum at a Cai of 100 muM to be approximately 10(-10) mol/cm2/s, which is about 1 order of magnitude less than that estimated for the sarcoplasmic reticulum of activated skeletal muscle in vivo. The release of most of the stored calcium in some experiments indicates that the observed permeability changes can occur over a large portion of the surface of the sarcoplasmic reticulum.     

Nutritional disorders between potassium,magnesium, calcium,and phosphorus in soil

A new soil testing procedure has been used to demonstrate the effect of an overfertilization by potassium during the preceding years. The total concentration of cations was governed by the amount of soluble anions and the proportion between the different cations was dependent on exchange reactions and is described by activity ratio. High activity ratio between potassium and calcium induced Ca-deficiency, which resulted in a restricted root functioning shown by periodic decreases of nutrient uptake rates and plant growth rate. P-deficiency restricted root growth, but although ammonium phosphate was most effective to increase P-concentration in soil extracts and P-absorption by plants, ordinary superphosphate gave the highest yield and the best utilization of the absorbed phosphorus, magnesium, and calcium.     

Transport mechanism for calcium and phosphate in ram spermatozoa

Calcium uptake into ejaculated ram spermatozoa is highly enhanced by the addition of extracellular phosphate. Under identical conditions, extracellular calcium stimulates the uptake of phosphate by the cells. Both calcium and phosphate uptake are comparably inhibited by the sulfhydryl reagent mersalyl. The I50 was found to be 6.36 and 10.14 nmol mersalyl per mg protein for phosphate and calcium uptake, respectively. Calcium uptake is inhibited by mersalyl whether phosphate is present or not. Extracellular fructose causes a 5-fold increase in calcium uptake. When fructose and phosphate are present in the cell's medium, there is an additive effect, which indicates that two independent systems are involved in calcium transport into the cell. Ruthenium red, which blocks Ca2+ transport into the mitochondria, causes 70% and 95% inhibition of calcium uptake in the absence or in the presence of fructose, respectively. Ruthenium red does not affect phosphate uptake unless calcium was present in the incubation medium. The stimulatory effect of fructose upon calcium uptake can be mimicked by L-lactate and can be inhibited by the glycolytic inhibitor 2-deoxyglucose. Fructose and L-lactate stimulate mitochondrial respiration in a comparable way. Oligomycin, which inhibits mitochondrial ATP synthesis, does not inhibit Ca2+ uptake. This indicates that ATP is not involved in the mechanism by which mitochondrial respiration stimulates Ca2+ uptake. The calcium channel blocker, verapamil, inhibits Ca2+ uptake in the presence or absence of extracellular phosphate. The phosphate-dependent calcium transport mechanism is more sensitive to verapamil than is the phosphate-independent transporter. In summary, the data indicate that the plasma membrane of mammalian spermatozoa contains a calcium/phosphate symporter, a phosphate-independent calcium carrier and a calcium-independent phosphate carrier.     

Caffeine eliminates gamma-ray-induced G2-phase delay in human tumor cells but not in normal cells.

It has been known for many years that caffeine reduces or eliminates the G2-phase cell cycle delay normally seen in human HeLa cells or Chinese hamster ovary (CHO) cells after exposure to X or gamma rays. In light of our recent demonstration of a consistent difference between human normal and tumor cells in a G2-phase checkpoint response in the presence of microtubule-active drugs, we examined the effect of caffeine on the G2-phase delays after exposure to gamma rays for cells of three human normal cell lines (GM2149, GM4626, AG1522) and three human tumor cell lines (HeLa, MCF7, OVGI). The G2-phase delays after a dose of 1 Gy were similar for all six cell lines. In agreement with the above-mentioned reports for HeLa and CHO cells, we also observed that the G2-phase delays were eliminated by caffeine in the tumor cell lines. In sharp contrast, caffeine did not eliminate or even reduce the gamma-ray-induced G2-phase delays in any of the human normal cell lines. Since caffeine has several effects in cells, including the inhibition of cAMP and cGMP phosphodiesterases, as well as causing a release of Ca(++) from intracellular stores, we evaluated the effects of other drugs affecting these processes on radiation-induced G2-phase delays in the tumor cell lines. Drugs that inhibit cAMP or cGMP phosphodiesterases did not eliminate the radiation-induced G2-phase delay either separately or in combination. The ability of caffeine to eliminate radiation-induced G2-phase delay was, however, partially reduced by ryanodine and eliminated by thapsigargin, both of which can modulate intracellular calcium, but by different mechanisms. To determine if caffeine was acting through the release of calcium from intracellular stores, calcium was monitored in living cells using a fluorescent calcium indicator, furaII, before and after the addition of caffeine. No calcium release was seen after the addition of caffeine in either OVGI tumor cells or GM2149 normal cells, even though a large calcium release was measured in parallel experiments with ciliary neurons. Thus it is likely that caffeine is eliminating the radiation-induced G2-phase delay through a Ca(++)-independent mechanism, such as the inhibition of a cell cycle-regulating kinase.     

Effect of fluoride, silicon, and magnesium on the mineralizing capacity of an inorganic medium and stone formers urine tested by a modified in vitro method

An in vitro mineralizing system using bovine achilles tendon developed by Thomas and Tomita (3) was modified to enable quantitative evaluation of mineralization. Using this modified method, the potential effect of various ions on the rate of calcium uptake from inorganic mineralization medium was measured. Of the elements tested, only silicon and fluoride accelerated calcium uptake, whereas magnesium had an inhibitory effect. The simultaneous presence of silicon and fluoride in the medium had a synergistic action on calcium uptake. Urine of stone formers showed high propensity to mineralize tendon collagen, but not the urine of non-stone formers. Total content, and concentration of silicon in urine of stone formers was significantly higher than in normal urine. Addition of silicon to non-stone formers urine enhanced its capacity to mineralize collagen in vitro. These results strongly suggest the possible involvement of silicon and fluoride in the genesis of urinary calculi in man.     

KB-R7943, a plasma membrane Na/Ca exchanger inhibitor,blocks opening of the mitochondrial permeability transition pore

The isothiourea derivative, KB-R7943, inhibits the reverse-mode of the plasma membrane sodium/calcium exchanger and protects against ischemia/reperfusion injury. The mechanism through which KB-R7943 confers protection, however, remains controversial. Recently, KB-R7943 has been shown to inhibit mitochondrial calcium uptake and matrix overload, which may contribute to its protective effects. While using KB-R7943 for this purpose, we find here no evidence that KB-R7943 directly blocks mitochondrial calcium uptake. Rather, we find that KB-R7943 inhibits opening of the mitochondrial permeability transition pore in permeabilized cells and isolated liver mitochondria. Furthermore, we find that this observation correlates with protection against calcium ionophore-induced mitochondrial membrane potential depolarization and cell death, without detrimental effects to basal mitochondrial membrane potential or complex I-dependent mitochondrial respiration. Our data reveal another mechanism through which KB-R7943 may protect against calcium-induced injury, as well as a novel means to inhibit the mitochondrial permeability transition pore.     

Calcium metabolism in HeLa cells and the effects of parathyroid hormone

Calcium metabolism was investigated in HeLa cells. 90% of the calcium of the cell monolayer is bound to an extracellular cell coat and can be removed by trypsin-EDTA. The calcium concentration of the naked cell, freed from its coat, is 0.47 mM. The calcium concentration of the medium does not affect the concentration of the naked cell calcium. However, the calcium of the cell coat is proportional to the calcium concentration in the medium. Calcium uptake into the cell coat increases with increasing calcium concentration of the medium, whereas uptake by the naked cell is independent of the calcium of the medium. Anaerobic conditions and metabolic inhibitors do not inhibit calcium uptake by the cell, a fact suggesting that this transfer is a passive phenomenon. The calcium in the extracellular cell coat, was not affected by parathyroid hormone. In contrast, the hormone increased the cellular calcium concentration by stimulating calcium uptake or by enhancing calcium binding to some cell components. These results suggest that, contrary to current thinking, parathyroid hormone influences the cellular calcium balance by mobilizing calcium from the extracellular fluids in order to increase its concentration in some cellular compartment. It is proposed that these effects can enhance calcium transport.     

1 alpha, 25-Dihydroxy-vitamin D-3 regulates ATP-dependent calcium transport in basolateral plasma membranes of rat enterocytes

Basolateral plasma membrane vesicles of rat small intestinal epithelium accumulate calcium through an ATP-dependent pumping system. The activity of this system is highest in duodenum and decreases towards the ileum. This distribution along the intestinal tract is similar as the active calcium absorption capacity of intact intestinal epithelial segments. ATP-dependent calcium uptake in basolateral membrane vesicles from duodenum and ileum increased significantly after repletion of young vitamin D-3-deficient rats with 1 alpha,25-dihydroxy-vitamin D-3. Ca2+ -ATPase activity in duodenal basolateral membranes increased to the same extend as ATP-dependent calcium transport, but (Na+ + K+)-ATPase activity remained unaltered.     

Calcium metabolism and enzyme secretion in guinea pig pancreas. Uptake, storage and release of calcium in whole cells and mitochondrial and microsomal fractions

In isolated pancreatic acinar cells from the guinea pig stimulation of enzyme secretion by carbamoylcholine is slightly diminished in the absence of extracellular Ca. LaCl3 in a concentration, which does not influence the secretory response to carbamoylcholine, nearly completely abolishes 45Ca uptake by cells, indicating that Ca uptake is not necessary for secretion. In cells preloaded with 45CaCl2, addition of carbamoylcholine leads to an immediate release of 45Ca, which can be blocked by atropine or 8-(N,N-diethylamino)-octyl 3,4,5-trimethoxybenzoate and is not influences by LaCl3 in concentrations, which do not inhibit secretion. A similar release of 45CaCl2 from preloaded cells is obtained by addition of the mitochondrial inhibitors antimycin A, carbonylcyanide p trifluoromethoxyphenylhydrazone (FCCP), and oligomycin. Possibly due to markedly diminished ATP levels, neither antimycin A nor FCCP act as secretagogues, both compounds being inhibitors of secretion. Oligomycin, which decreases ATP levels only to 20%, stimulates secretion. Mitochondria and microsomes from pancreatic tissue are able to accumulate 45Ca. Mitochondrial 45Ca uptake can be driven by ATP or active respiration and is inhibited by NaN3, oligomycin, antimycin A or FCCP. Microsomal 45Ca uptake is ATP-dependent. NaN3 and mitochondrial inhibitors have no influence on microsomal 45Ca uptake, which is stimulated several-fold by oxalate. The results support the assumption, that in the guinea pig pancreas Ca mobilization from intracellular stores is necessary to initiate secretion. Due to their ability for an active accumulation of45Ca both mitochondria and microsomes could serve as intracellular calcium stores.     

Effect of taurine on passive ion transport in rat brain synaptosomes.

Taurine, in concentrations greater than 10 mM, was found to have an inhibitory effect on passive calcium uptake and release in rat brain synaptosomal preparations. Amino acids similar to that of taurine in chemical structure, β-alanine, hypotaurine, homotaurine and γ-amino-butyric acid were also shown to inhibit calcium uptake in this preparation. Taurine, though, did not alter the permeability of these preparations to sodium or potassium. It thus appears that taurine and chemically related amino acids can alter calcium movements in these preparations. It is postulated that this effect is due to binding to specific taurine sites in the synaptosomal membranes.     

Energy-dependent calcium transport in endoplasmic reticulum of adipocytes.

The endoplasmic reticulum from isolated rat adipocytes has the ability to actively accumulate calcium. The calcium uptake was characterized using the 20,000 X g supernatant (S1 fraction) of total cellular homogenate. Endoplasmic reticulum vesicles isolated from the S1 fraction as a 160,000 X g microsomal pellet prior to testing demonstrated little ability to accumulate calcium. The calcium uptake in the S1 fraction was localized to the endoplasmic reticulum vesicles by morphologic appearance, by the use of selective inhibitors of calcium uptake, and by high speed sedimentation of the accumulated calcium. The uptake was MgATP- and temperature-dependent and was sustained by the oxalate used as the intravesicular trapping agent. Uptake was linear with time for at least 30 min at all calcium concentrations tested (3 to 100 muM) and exhibited a pH optimum of approximately 7.0. The sulfhydryl inhibitor p-chloromercuribenzene sulfonate produced a dose-dependent inhibition of calcium uptake with total inhibition at 0.07 mumol/mg protein. Ruthenium red and sodium azide inhibited less than 5% of the uptake at concentrations (5 muM and 10 mM, respectively) which completely blocked calcium uptake by mitochondria isolated from the same cells. The Km for calcium uptake was 10 muM total calcium which corresponded to approximately 3.6 muM ionized calcium in the assay system. The maximum velocity of the uptake was 5.0 nmol (mg of microsomal protein)-1 (min)-1 at 24 degrees under the assay conditions used and exhibited a Q10 of 1.8. The uptake activity of the endoplasmic reticulum vesicles in the S1 fraction exhibited a marked time- and temperature-dependent lability which might account in part for the lack of uptake in the isolated microsomal fraction. This energy-dependent calcium uptake system would appear to be of physiologic importance to the regulation of intracellular calcium.     

Evidence for a halothane-dependent cyclic flux of calcium in rat-liver mitochondria.

The previously reported (Hall et al., Biochem. Soc. Trans. 1973) halothane-dependent, calcium-induced loss of respiratory control in rat liver mitochondria is relatively specific to calcium; the effect of strontium ions is much smaller, and comparable additions of potassium salts have no effect on mitochondrial respiration on succinate in the presence of halothane. The calcium-dependent loss of respiratory control can be prevented, or reversed, respectively, by the prior or subsequent addition of agents that either chelate extramitochondrial Ca2plus or inhibit calcium accumulation, or that inhibit the efflux of accumulatec calcium. These results suggest that the halothane-dependent, calcijm-induced loss of respiratory control is due to a cyclic flux of calcium uptake and release.