Facilitated transport of calcium by cells and subcellular membranes of Bacillus subtilis and Escherichia coli.

The level of calcium in growing cells is lower than that in the growth medium. Non-energy-dependent uptake of 45-Ca by log-phase cells of Bacillus subtilis occurs under two conditions: at 0 C or in the presence of m-chlorophenyl carbonylcyanide hydrazone. Similar uptake, but quantitatively less, occurs with Escherichia coli cells under the same conditions. Membrane vesicles prepared from B. subtilis or E. coli accumulate 45-Ca by a process that does not depend on added energy sources and is not inhibited by the respiratory poison cyanide. The properties of calcium transport in all cases is consistent with carrier-mediated, facilitated transport with specificity Ca-2+ greater than Sr-2+ greater than Mn-2+ greater than Mg-2+. Upon transfer of cells from 0 C to 20 C, pre-accumulated 45-Ca is released. Heat-killed cells do not accumulate 45-Ca and calcium is released by cells upon addition of toluene (under conditions that do not cause visible lysis). These results suggest that the facilitated uptake of calcium may be utilizing a transport system that normally is responsible for the energy-dependent excretion of calcium from the cells.     

Studies on the role of calcium ions in the stimulation by adrenaline of amylase release from rat parotid

1. Mitochondrial and microsomal fractions were prepared from rat parotid glands. Both fractions were able to take up (45)Ca. The mitochondrial (45)Ca-uptake system could be driven by ATP (energy-coupled Ca(2+) uptake) or by ADP+succinate (respiration-coupled Ca(2+) uptake). Energy-coupled Ca(2+) uptake was blocked by oligomycin but not by carbonyl cyanide m-chlorophenylhydrazone; respiration-coupled Ca(2+) uptake was blocked by carbonyl cyanide m-chlorophenylhydrazone but not by oligomycin. Microsomal Ca(2+) uptake was dependent on the presence of ATP; the ATP-dependent Ca(2+) uptake was not affected by oligomycin or carbonyl cyanide m-chlorophenylhydrazone. Ca(2+) uptake by both fractions was inhibited by Ni(2+). 2. Incubation of parotid pieces with adrenaline increased the rate of release of amylase and the uptake of (45)Ca. The adrenaline-stimulated release of amylase was not dependent on the presence of extracellular Ca(2+). 3. The effect of adrenaline on the subcellular distribution of (45)Ca in parotid pieces incubated with (45)Ca was studied. In parotid tissue incubated with (45)Ca, both mitochondrial and microsomal fractions contained (45)Ca. Incubation with adrenaline increased the amount of (45)Ca incorporated into the mitochondrial fraction but not the microsomal fraction. In parotid tissue preloaded with (45)Ca subsequent incubation with adrenaline caused a decrease in the amount of (45)Ca found in both the mitochondrial and microsomal fractions. 4. From these data we conclude that the regulation of the cytosolic Ca(2+) concentration in the parotid may involve both mitochondrial and microsomal Ca(2+)-uptake systems. We suggest that the action of adrenaline on the parotid may be to increase the movement of Ca(2+) to the cytosol by increasing the flux of Ca(2+) across mitochondrial, microsomal and plasma membranes.     

Glucose inhibits 45Ca efflux from pancreatic beta-cells also in the absence of Na+-Ca2+ countertransport

During perifusion with medium deprived of Ca2+, addition of glucose or omission of Na+ resulted in prompt and quantitatively similar inhibitions of 45Ca efflux from beta-cell rich pancreatic islets microdissected from ob/ob mice. Glucose had no additional inhibitory effect when Na+ was isoosmotically replaced by sucrose or choline+. When K+ was used as a substitute for Na+, the inhibitory effect of Na+ removal on 45Ca efflux became additive to that of glucose. The observation that glucose can be equally effective in inhibiting 45Ca efflux in the presence or absence of Na+ is difficult to reconcile with the postulate that the Na+-Ca2+ countertransport mechanism is a primary site of action for glucose.     

Calcium and pancreatic beta-cell function. 7. Evidence for cyclic AMP-induced translocation of intracellular calcium

The effect of cyclic AMP on calcium movements in the pancreatic beta-cell was evaluated using an experimental approach based on in situ labelling of intracellular organelles of ob/ob-mouse islets with 45Ca. Whereas the glucose-stimulated 14Ca incorporation by mitochondria and secretory granules was increased under a condition known to reduce cyclic AMP (starvation), raised levels of this nucleotide (addition of 3-isobutyl-1-methylxanthine or N6,O2'-dibutyryl adenosine 3',5'-cyclic monophosphate) reduced the mitochondrial accumulation of 45Ca. Conditions with increased cyclic AMP were associated with a stimulated efflux of 45Ca from the secretory granules but not from the mitochondria. The microsomal fraction differed from both the mitochondrial and secretory granule fractions by accumulating more 45Ca after the addition of 3-isobutyl-1-methylxanthine. The results suggest that cyclic AMP potentiates glucose-stimulaated insulin release by increasing cytoplasmic Ca2+ at the expense of the calcium taken up by the organelles of the pancreatic beta-cells.     

Calcium distribution in islets of Langerhans: a study of calcium concentrations and of calcium accumulation in B cell organelles.

Calcium concentrations of various pancreatic B cell organelles have been determined by X-ray microanalysis of areas of frozen sections of unfixed rat islets of Langerhans. Highest concentrations were detected in storage granules and in mitochondria, although calcium was also present in nuclei, in areas of endoplasmic reticulum and of cytoplasm. Accumulation of 45Ca by isolated organelles has been studied in homogenates and isolated subcellular fractions of rat islets of Langerhans. In the presence of a permeant anion (oxalate or phosphate), accumulation of 45Ca into mitochondria and microsomes was strongly stimulated by ATP. This net uptake was diminished during incubation of homogenates or of a mitochondria plus storage granule-rich fraction in the presence of cyclic AMP, dibutyryl cyclic GMP; 2:4-dinitrophenol or of ruthenium red. Investigations of the characteristics of 45Ca accumulation by homogenates prepared from storage granule-depleted islets showed no differences from those of normal islets, suggesting that the granules do not represent an important labile pool of calcium. With the exception of cyclic AMP and cyclic GMP none of the insulin secretagogues tested (glucose, leucine, arginine, adrenalin, noradrenalin, theophylline, glibenclamide) altered calcium accumulation by islet homogenates. On the basis of absolute calcium levels and of 45Ca uptake studies it is concluded that islet B cells contain a readily exchangeable mitochondrial calcium pool, and an endoplasmic reticulum pool containing a lower concentration of calcium which is also readily exchangeable. The storage granules, despite their high calcium content, do not appear to constitute a labile pool. It seems likely that the labile mitochondria and endoplasmic reticulum pools play a predominant role in the regulation of cytoplasmic free calcium levels, which may in turn be important in the regulation of rates of insulin secretion.     

Site density of the sodium-calcium exchange carrier in reconstituted vesicles from bovine cardiac sarcolemma

The site density of the Na2+-Ca2+ exchanger in bovine cardiac sarcolemma was estimated from measurements of the fraction of reconstituted proteoliposomes exhibiting exchange activity. Sarcolemmal vesicles were solubilized with 1% Triton X-100 in the presence of either 100 mM NaCl or 100 mM KCl; after a 20-40-min incubation period on ice, sufficient KCl, NaCl, CaCl2, and soybean phospholipids were added to each extract to give final concentrations of 40 mM NaCl, 120 mM KCl, 0.1 mM CaCl2, and 10 mg/ml phospholipid. These mixtures were then reconstituted into proteoliposomes, and the rate of 45Ca2+ isotopic exchange was measured under equilibrium conditions. Control studies showed that Na+-Ca2+ exchange activity was completely lost if Na+ was not present during solubilization. The difference in 45Ca2+ uptake between vesicles initially solubilized in the presence or absence of NaCl therefore reflected exchange activity and corresponded to 3.1 +/- 0.3% of the total 45Ca2+ uptake by the entire population of vesicles, as measured in the presence of the Ca2+ ionophore A23187. Assuming that each vesicle with exchange activity contained 1 molecule of the Na+-Ca2+ exchange carrier, a site density of 10-20 pmol/mg of protein for the exchanger was calculated. The Vmax for Na+-Ca2+ exchange activity in the proteoliposomes was approximately 20 nmol/mg of protein.s which indicates that the turnover number of the exchange carrier is 1000 s-1 or more. Thus, the Na+-Ca2+ exchanger is a low density, high turnover transport system.     

Stimulation of glucose transport in skeletal muscle by the sodium ionophore monensin

The tissue/medium distribution of the nonmetabolized glucose analog 3-O-methyl-D-glucose was measured in mouse diaphragm muscle and related to changes in 45Ca influx, Na+ content and Na+-pump activity. In the presence of external Ca2+ the sodium ionophore monensin greatly increased cellular Na+ content (and decreased K+ content) although 86Rb uptake, reflecting Na+-pump activity was increased. Concomitantly, 45Ca influx was stimulated, presumably through activation of Na+-Ca2+ exchange. In parallel to the rise in Ca2+ influx sugar transport was also increased. Sugar transport was also increased by monensin in the nominal absence of external Ca2+, when Ca2+ influx was minimal. To test if monensin releases Ca2+ from intracellular storage sites in the absence of external Ca2+, the ionophore was added to medium perfusing rat hind limb preparations and the total Ca content of muscle mitochondria was determined. When Ca2+ was present in the perfusate, monensin increased the mitochondrial Ca content. In the absence of Ca2+, the mitochondrial Ca content was lower and was further depressed by monensin, suggesting that elevation of internal Na+ by monensin may increase mitochondrial Ca2+ loss via activation of Na+-Ca2+ exchange across the mitochondrial membrane. The above results are consistent with the effect of monensin on sugar transport being due to alterations in Ca2+ distribution. They support the earlier conclusion that regulation of sugar transport in muscle is Ca2+ dependent.     

The use of calcium uptake by small amounts of mitochondria from pancreatic islets to study mitochondrial respiration: the effects of diazoxide and sodium

The net uptake of 45Ca into mitochondria from pancreatic islets is stimulated by substrates that transfer reducing equivalents to various sites of the respiratory chain, such as succinate or glycerol 3-phosphate (site II), malate plus pyruvate (site I) or ascorbate plus TMPD (site III). Diazoxide, a known inhibitor of insulin release in vivo and in vitro, strongly inhibited net 45Ca uptake supported by glycerol phosphate and succinate and weakly inhibited 45Ca uptake supported by the other substrates. These results suggest that diazoxide, although not completely specific, is predominately an inhibitor at site II of the respiratory chain. This result is consistent with previous work that showed diazoxide inhibits the enzyme activity of the mitochondrial glycerol phosphate dehydrogenase in islets. Sodium ion inhibited the net accumulation of 45Ca by islet mitochondria suggesting a similarity between islet mitochondria and those of heart and some other endocrine tissues.     

Na+-Ca2+ exchanger in the soluble fraction of crayfish striated muscle

Proteins with Na+-Ca2+ exchange activity from the soluble fraction of crayfish striated muscle were inserted into asolectin proteoliposomes. A pH dependent calcium uptake with an optimum at the alkaline side and inhibition in the presence of sodium or strontium ions in the external medium was observed. When expressed per tissue wet weight the capacity for Na+-Ca2+ exchange of proteoliposomes with inserted soluble proteins was by one half higher than that of the membrane fraction and more than twice higher in comparison with the reconstituted membrane bound exchanger. Using polyacrylamide gel electrophoresis two most prominent proteins with Mr over 200 and 43 kDa could be detected in proteoliposomes with the highest Na+-Ca2+ exchange. It is assumed that protein(s) with Mr 43 kDa could represent the soluble Na+-Ca2+ exchanger in crayfish striated muscle soluble fraction.     

Decrease in insulin-containing secretory granules and mitochondrial gene expression in mouse pancreatic islets maintained in culture following streptozotocin exposure

We have previously described a preferential reduction in the secretory response to nutrient secretagogues in pancreatic mouse islets maintained in culture after in vitro exposure to streptozotocin (SZ). This reduction was associated with an impaired substrate metabolism at the mitochondrial level. To further clarify this issue, mouse pancreatic islets were exposed in vitro to 2.2 mM SZ for 30 min. At 4 h after SZ treatment ultrastructural changes were apparent in the endoplasmic reticulum and Golgi areas of the B-cells. However, 2 and 6 days following SZ exposure the B-cells appeared well preserved, except for a marked decrease in the number of insulin-containing secretory granules. A morphometric analysis of the B-cells 6 days after SZ exposure showed a normal B-cell size and a normal volume fraction of B-cell mitochondria. However, there was a decrease in total islet size and a 13% decrease in the volume fraction of B-cells in the islets. These mouse islets exhibited a decreased content of the mitochondrial DNA-encoded cytochrome b mRNA, as evaluated by dot-blot analysis. As a whole, the data obtained indicate that SZ treatment does not induce a decrease in the number of mitochondria or long-lasting ultrastructural damage to this organelle. However, there is a clear decrease in the cytochrome b mRNA, suggesting that SZ can induce damage to the mitochondrial DNA.     

Decrease in insulin-containing secretory granules and mitochondrial gene expression in mouse pancreatic islets maintained in culture following streptozotocin exposure.

We have previously described a preferential reduction in the secretory response to nutrient secretagogues in pancreatic mouse islets maintained in culture after in vitro exposure to streptozotocin (SZ). This reduction was associated with an impaired substrate metabolism at the mitochondrial level. To further clarify this issue, mouse pancreatic islets were exposed in vitro to 2.2 mM SZ for 30 min. At 4 h after SZ treatment ultrastructural changes were apparent in the endoplasmic reticulum and Golgi areas of the B-cells. However, 2 and 6 days following SZ exposure the B-cells appeared well preserved, except for a marked decrease in the number of insulin-containing secretory granules. A morphometric analysis of the B-cells 6 days after SZ exposure showed a normal B-cell size and a normal volume fraction of B-cell mitochondria. However, there was a decrease in total islet size and a 13% decrease in the volume fraction of B-cells in the islets. These mouse islets exhibited a decreased content of the mitochondrial DNA-encoded cytochrome b mRNA, as evaluated by dot-blot analysis. As a whole, the data obtained indicate that SZ treatment does not induce a decrease in the number of mitochondria or long-lasting ultrastructural damage to this organelle. However, there is a clear decrease in the cytochrome b mRNA, suggesting that SZ can induce damage to the mitochondrial DNA.     

A study of dependence of protein synthesis in mitochondria on the transmembrane potential

Summary 1. Incorporation of [H³]leucine into the TCA insoluble fraction of rat liver mitochondria incubatedin vitro is inhibited by uncouplers of oxidative phosphorylation. The inhibition is not correlated with the activation of mitochondrial ATPase. 2. Dependence of mitochondrial protein synthesis on the transmembrane potential is manifested in a wide range of K⁺ and Mg⁺⁺ concentrations in the incubation media. 3. The inhibitory action of uncouplers shows a lag period equal to 5–7 minutes, this lag period however is not observed when the uncoupler is added to puromycin-treated mitochondria. 4. Dependence of mitochondrial protein synthesis on the transmembrane potential, which represents a property characteristic for the inner mitochondrial membrane suggests that mitochondrial ribosomes act in close contact with the mitochondrial membrane system.Abbreviations MPS mitochondrial protein synthesis - CAP chloramphenical - CCP 2,4,6-chlorocarbonyl cyanide phenylhydrazone - FCCP p-trifluoromethoxy carbonyl cyanide phenylhydrazone - PEP phosphoenolpyruvate - Pi inorganic phosphate     

Calcium and pancreatic β-cell function 7. Evidence for cyclic AMP-induced translocation of intracellular calcium

The effect of cyclic AMP on calcium movements in the pancreatic β-cell was evaluated using an experimental approach based on in situ labelling of intracellular organelles of ob/ob-mouse islets with ⁴⁵Ca. Whereas the glucose-stimulated ⁴⁵Ca incorporation by mitochondria and secretory granules was increased under a condition known to reduce cyclic AMP (starvation), raised levels of this nucleotide (addition of 3-isobutyl-1-methylxanthine or N⁶,O^2′-dibutyryl adenosine 3′,5′-cyclic monophosphate) reduced the mitochondrial accumulation of ⁴⁵Ca. Conditions with increased cyclic AMP were associated with a stimulated efflux of ⁴⁵Ca from the secretory granules but not from the mitochondria. The microsomal fraction differed from both the mitochondrial and secretory granule fractions by accumulating more ⁴⁵Ca after the addition of 3-isobutyl-1-methylxanthine. The results suggest that cyclic AMP potentiates glucose-stimulated insulin release by increasing cytoplasmic Ca²⁺ at the expense of the calcium taken up by the organelles of the pancreatic β-cells.     

ISOLATION AND PROPERTIES OF SECRETORY GRANULES FROM RAT ISLETS OF LANGERHANS : I. Isolation of a Secretory Granule Fraction

A method has been devised for the isolation of a secretory granule fraction from isolated rat islets of Langerhans. The islets were homogenized in buffered sucrose, and the homogenate was separated into nuclear, mitochondrial, secretory granule, and microsomal fractions by differential centrifugation. The secretory granule fraction was purified by differential centrifugation in discontinuous sucrose density gradients. A greater degree of purification could be achieved by the use of two successive gradients of this type, although the final yield was greatly reduced. Biochemical and morphological characterization of the fractions was obtained; the secretory granule fraction contained both insulin and glucagon. The limiting membranes of the granules remained intact and the general appearance of the granules was similar to that seen within the whole islet cells.     

The interaction between manganese and calcium fluxes in pancreatic beta-cells.

Electrothermal atomic-absorption spectroscopy was employed for measuring manganese in beta-cell-rich pancreatic islets isolated from ob/ob mice. The efflux from preloaded islets was estimated from the amounts remaining after 30 min of subsequent test incubations in the absence of Mn2+. An increase in the extracellular Mg2+ concentration promoted the Mn2+ efflux and removal of Na+ from a Ca2+-deficient medium had the opposite effect. Addition of 25 mM-K+ failed to affect Mn2+ outflow as did 3-isobutyl-1-methylxanthine and dibutyryl cyclic AMP. Whereas tolbutamide caused retention of manganese, the ionophore Br-X537A promoted an efflux. D-Glucose was equally potent in retaining the islet manganese when the external Ca2+ concentration ranged from 15 microM to 6.30 mM. Subcellular-fractionation experiments indicated a glucose-stimulated incorporation of manganese into all fractions except the microsomes. The effect was most pronounced in the mitochondrial fraction, being as high as 164%. The glucose-induced uptake of intracellular 45Ca was abolished in the presence of 0.25 mM-Mn2+. When added to medium containing 2.5 mM-Mn2+, glucose even tended to decrease 45Ca2+ uptake. The inhibitory effect of Mn2+ was apparent also from a diminished uptake of 45Ca into all subcellular fractions. The efflux of 45Ca2+ was markedly influenced by Mn2+ as manifested in a prominent stimulation followed by inhibition. In addition to demonstrating marked interactions between fluxes of Mn2+ and Ca2+, the present studies support the view that the glucose inhibition of the efflux of bivalent cations from pancreatic beta-cells is accounted for by their accumulation in the mitochondria.     

Purification of the cardiac Na+-Ca2+ exchange protein

We have used fractionation procedures to enrich solubilized cardiac sarcolemma in the Na+-Ca2+ exchange protein. Sarcolemma is extracted with an alkaline medium to remove peripheral proteins and is then solubilized with decylmaltoside. Next, the exchanger is applied to DEAE-Sepharose and eluted with high salt. The DEAE fraction is applied to WGA-agarose, and a small fraction of protein, enriched in the exchanger, can be eluted by changing the detergent to Triton X-100. This fraction is reconstituted into asolectin proteoliposomes for measurement of Na+-Ca2+ exchange activity and gel electrophoresis. The purified fraction has a Na+-Ca2+ exchange activity of 600 nmol Ca2+/mg of protein per s at 10 microM Ca2+ and a purification factor of about 30 as compared with control reconstituted sarcolemmal vesicles. Ca2+-Ca2+ exchange and Na+-Ca2+ exchange activities were both present in the same final reconstituted vesicles indicating that the same protein is responsible for both transport activities. SDS-PAGE reveals two prominent protein bands at 70 and 120 kDa. After mild chymotrypsin treatment (1 microgram/ml), there is no loss of exchange activity, but the 120 kDa band disappears and the 70 kDa band becomes more dense. This suggests that the 70 kDa band is due to an active proteolytic fragment of the 120 kDa protein. Under non-reducing gel conditions, only a single protein band is seen with an apparent molecular weight of 160 kDa. Antibodies to the purified exchanger preparation are able to immunoprecipitate exchange activity and confirm that the 70 kDa protein derives from the 120 kDa protein. We propose that both the 70 and 120 kDa proteins are associated with the Na+-Ca2+ exchanger.     

Metabolic, cationic and secretory response to D-glucose in depolarized and Ca(2+)-deprived rat islets exposed to diazoxide

D-glucose stimulates insulin release from islets exposed to both diazoxide, to activate ATP-responsive K+ channels, and a high concentration of K+, to cause depolarization of the B-cell plasma membrane. Under these conditions, the insulinotropic action of D-glucose is claimed to occur despite unaltered cytosolic Ca2+ concentration, but no information is so far available on the changes in Ca2+ fluxes possibly caused by the hexose. In the present experiments, we investigated the effect of D-glucose upon 45Ca efflux from islets exposed to both diazoxide and high K+ concentrations. In the presence of diazoxide and at normal extracellular Ca2+ concentration, D-glucose (16.7 mmol/l) inhibited insulin release at 5 mmol/l K+, but stimulated insulin release of 90 mmol/l K+. In both cases, the hexose inhibited 45Ca outflow. In the presence of diazoxide, but absence of Ca2+, D-glucose (8.3 to 25.0 mmol/l) first caused a rapid decrease in insulin output followed by a progressive increase in secretory rate. This phenomenon was observed both at 5 mmol/l or higher concentrations (30, 60 and 90 mmol/l) of extracellular K+. It coincided with a monophasic decrease in 45Ca efflux and either a transient (at 5 mmol/l K+) or sustained (at 90 mmol/l K+) decrease in overall cytosolic Ca2+ concentration. The decrease in 45Ca efflux could be due to inhibition of Na(+)-Ca2+ countertransport with resulting localized Ca2+ accumulation in the cell web of insulin-producing cells. A comparable process may be involved in the secretory response to D-glucose in islets exposed to diazoxide and a high concentration of K+ in the presence of extracellular Ca2+.     

The malate-aspartate NADH shuttle member Aralar1 determines glucose metabolic fate, mitochondrial activity, and insulin secretion in beta cells

The NADH shuttle system, which transports reducing equivalents from the cytosol to the mitochondria, is essential for the coupling of glucose metabolism to insulin secretion in pancreatic beta cells. Aralar1 and citrin are two isoforms of the mitochondrial aspartate/glutamate carrier, one key constituent of the malate-aspartate NADH shuttle. Here, the effects of Aralar1 overexpression in INS-1E beta cells and isolated rat islets were investigated for the first time. We prepared a recombinant adenovirus encoding for human Aralar1 (AdCA-Aralar1), tagged with the small FLAG epitope. Transduction of INS-1E cells and isolated rat islets with AdCA-Aralar1 increased aralar1 protein levels and immunostaining revealed mitochondrial localization. Compared with control INS-1E cells, overexpression of Aralar1 potentiated metabolism secretion coupling stimulated by 15 mm glucose. In particular, there was an increase of NAD(P)H generation, of mitochondrial membrane hyperpolarization, ATP levels, glucose oxidation, and insulin secretion (+45%, p < 0.01). Remarkably, this was accompanied by reduced lactate production. Rat islets overexpressing Aralar1 secreted more insulin at 16.7 mm glucose (+65%, p < 0.05) compared with controls. These results show that aspartate-glutamate carrier capacity limits glucose-stimulated insulin secretion and that Aralar1 overexpression enhances mitochondrial metabolism.     

Effects of local anesthetics and hemicholinium-3 on 45-Ca efflux in barnacle muscle fibers.

Benzocaine, which occurs in the uncharged form in the physiological range of pH, caused inhibition of 45-Ca efflux in branacle muscle fibers. By contrast, in the presence of a low external Ca-2+ concentration it produced stimulation of the efflux. Both the inhibitory and stimulatory actions of benzocaine appeared to be less potent than those of procaine. Hemicholinium-3 (HC-3), on the other hand, which exists only in the charged form, caused a large stimulation of the 45-Ca efflux following microinjection, and the potency of this action was found to be at least 10 times greater than that of procaine. External application of HC-3 produced inhibition occasionally. Effects of tetracaine were similar to those produced by procaine; however, its inhibitory action was greater in more alkaline solution, which is the opposite of that observed with procaine. Lidocaine produced a less consistent effect than procaine; the inhibitory action of the former was less potent but the stimulatory action of the two anesthetics were comparable, p-Aminobenzoic acid was without effect on 45-Ca efflux. These results indicate that both the charged and uncharged forms of local anesthetics are capable of causing stimulatory and inhibitory effects on 45-Ca efflux in barnacle muscle fibers, and that the inhibition produced is the result of action on the CA-Ca exchange system whereas the stimulation is the result of release of Ca from internal storage sites.     

Cyanide-insensitive respiration in relation to growth of a low-temperature basidiomycete

The cyanogenic low-temperature basidiomycete (Coprinus psychromorbidus Redhead and Traquair), unlike other cyanide-tolerant fungi, does not detoxify cyanide via formamide hydro-lyase. Instead, tolerance apparently depends on cyanide-insensitive respiration involving activity of the mitochondrial alternative oxidase. Respiration and growth of young mycelium that lacks alternative oxidase activity are blocked both by cyanide and 1 mum antimycin. When activity of the alternative oxidase is elicited in young mycelium by 0.05 mm cyanide, subsequent treatment with antimycin stimulates respiration and fails to halt growth. Older mycelium becomes tolerant coincidentally with the release of cyanide by the mycelium. Tolerant older mycelium in medium containing 0.05 to 1.0 mum antimycin grows at 30 to 45% of the control rate. Cyanide- and antimycin-tolerant growth and respiration are blocked by salicyl hydroxamic acid, an inhibitor of the alternative oxidase, and by rotenone, which inhibits ATP synthesis at site I.