Casein kinase activity in rat mammary gland Golgi vesicles. Demonstration of latency and requirement for a transmembrane ATP carrier.

A Golgi vesicle-enriched preparation from mammary tissue of lactating rats has been used to investigate the phosphorylation of caseins in vitro. Casein kinase, together with its casein substrates, is enclosed within the lumen of Golgi membrane vesicles and has a requirement for Ca2+ and ATP. The permeability characteristics of the Golgi membrane to ATP and Ca2+ therefore have a possible regulatory influence on casein kinase activity. This influence has been investigated by alteration of the permeability characteristics by using several agents having differing degrees of selectivity. The ionophore A23187, which permits loss of Ca2+ from the vesicles, caused a decrease in casein phosphorylation which could be reversed by externally supplied Ca2+. Alamethicin, an ionophore that creates larger transmembrane channels, caused an increase in casein phosphorylation. This increase showed a requirement for divalent metal ions which could be satisfied by either Ca2+ or Mn2+. Under the same conditions, La3+ was inhibitory. Triton X-100 caused loss of intravesicular Ca2+, yet this was accompanied by an increase in phosphate incorporation into the caseins. We conclude from these results that the binding site on casein kinase for ATP is within the Golgi membrane barrier and that they imply the presence of a transmembrane ATP-transport mechanism. Inhibition of casein phosphorylation by atractyloside and carboxyatractyloside lends support to this concept.     

Calcium and magnesium regulation of phosphorylation by ATP and ITP in sarcoplasmic reticulum vesicles.

Membrane phosphorylation and nucleoside triphosphatase activity of sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle were studied using ATP and ITP as substrates. The Ca2+ concentration was varied over a range large enough to saturate either the high affinity Ca2+-binding site or both high and low affinity binding sites. In intact vesicles, which are able to accumulate Ca2+, the steady state level of enzyme phosphorylated by either ATP or ITP is already high in 0.02 mM Ca2+ and does not vary as the Ca2+ concentration is increased to 10 mM. Essentially the same pattern of membrane phosphorylation by ATP is observed when leaky vesicles, which are unable to accumulate Ca2+, are used. However, for leaky vesicles, when ITP is used as substrate, the phosphoenzyme level increases 3- to 4-fold when the Ca2+ concentration is raised from 0.02 to 20 mM. When Mg2+ is omitted from the assay medum, the degree of membrane phosphorylation by ATP varies with Ca2+ in the same way as when ITP is used in the presence of Mg2+. Membrane phosphorylation of leaky vesicles by either ATP or ITP is observed in the absence of added Mg2+. When these vesicles are incubated in media containing ITP and 0.1 mM Ca2+, addition of Mg2+ up to 10 mM simultaneously decreases the steady state level of phosphoenzyme and increases the rate of ITP hydrolysis. When ATP is used, the addition of 10 mM Mg2+ increases both the steady state level of phosphoenzyme and the rate of ATP hydrolysis. When the Ca2+ concentration is raised to 10 or 20 mM, the degree of membrane phosphorylation by either ATP or ITP is maximal even in the absence of added Mg2+ and does not vary with the addition of 10 mM Mg2+. In these conditions the ATPase and ITPase activities are activated by Mg2+, although not to the level observed in 0.1 mM Ca2+. An excess of Mg2+ inhibits both the rate of hydrolysis and membrane phosphorylation by either ATP or ITP.     

Calcium-dependent Golgi-vesicle fusion and cathepsin B in the conversion of proalbumin into albumin in rat liver.

1. An enzyme from rat liver that converts proalbumin into albumin is described. Partial purification, inhibitor studies and the conditions for maximum activity suggest that the enzyme is cathepsin B. 2. A membrane-bound enzyme, located mainly in lysosomes, also converts proalbumin into albumin. This appears to be a membrane-bound form of cathepsin B. 3. Isolated Golgi vesicles, incubated under conditions suitable for cathepsin B, convert endogenous proalbumin into albumin. 4. This conversion in Golgi vesicles has an absolute requirement for Ca2+ at micromolar concentrations. Mg2+ does not affect or substitute for Ca2+. Both the proalbumin and the albumin formed from it are intravesicular. 5. Converting activity is enhanced by pretreatment with the known chemical fusogen, poly(ethyleneglycol). 6. Vesicles preincubated at pH above 7 in the presence of dithiothreitol show a marked fall in converting activity. This can be partially restored by incubation with native vesicles. These results suggest that vesicle fusion is a requirement for conversion of proalbumin into albumin.     

Ca2+ transport and Ca2+-dependent ATP hydrolysis by Golgi vesicles from lactating rat mammary glands.

Ca2+ transport across mammary-gland Golgi membranes was measured after centrifugation of the membrane vesicles through silicone oil. In the presence of 2.3 microM free Ca2+ the vesicles accumulated 5.8 nmol of Ca2+/mg of protein without added ATP, and this uptake was complete within 0.5 min. In the presence of 1 mM-ATP, Ca2+ was accumulated at a linear rate for 10 min after the precipitation of intravesicular Ca2+ with 10 mM-potassium oxalate. ATP-dependent Ca2+ uptake exhibited a Km of 0.14 microM for Ca2+ and a Vmax. of 3.1 nmol of Ca2+/min per mg of protein. Ca2+-dependent ATP hydrolysis exhibited a Km of 0.16 microM for Ca2+ and a Vmax. of 10.1 nmol of Pi/min per mg of protein. The stoichiometry between ATP-dependent Ca2+ uptake and Ca2+-stimulated ATPase varied between 0.3 and 0.7 over the range 0.03-8.6 microM-Ca2+. Both Ca2+ uptake and Ca2+-stimulated ATPase were strongly inhibited by orthovanadate, which suggests that the major mechanism by which Golgi vesicles accumulate Ca2+ is through the action of the Ca2+-stimulated ATPase. However, Ca2+ uptake was also decreased by the protonophore CCCP (carbonyl cyanide m-chlorophenylhydrazone), indicating that it may occur by other mechanisms too. The effect of CCCP may be related to the existence of transmembrane pH gradients (delta pH) in these vesicles: the addition of 30 microM-CCCP reduced delta pH from a control value of 1.06 to 0.73 pH unit. Golgi vesicles also possess a Ca2+-efflux pathway which operated at an initial rate of 0.5-0.57 nmol/min per mg of protein.     

Characterization of right-side-out membrane vesicles rich in (Na,K)-ATPase and isolated from dog kidney outer medulla

When purified on a sucrose gradient, basolateral membranes from dog kidney outer medulla are found to be very rich in (Na,K)-ATPase; about 50% of the membrane protein is comprised of this enzyme. (Na,K)-ATPase activity is activated 3- to 5-fold by detergent treatment, and this has been previously attributed to the impermeable vesicular nature of the membranes. Porcine trypsin inactivates only that fraction of (Na,K)-ATPase activity seen without detergent, consistent with a right-side-out orientation of membrane vesicles; the trypsin sensitivity and detergent activation of [3H]ouabain binding in the presence of Na+ + Mg2+ + ATP or Mg2+ + Pi are also consistent with this hypothesis. Using nearly isosmotic Hypaque density gradient centrifugation a population of impermeable right-side-out membrane vesicles (H1) is separated from a leaky population (H2). (Na,K)-ATPase activity in the H1 population is 20-fold activated by detergent and insensitive to porcine trypsin. The vesicle volume is 2.4 microliters/mg, and monovalent cations passively equilibrate with the intravesicular volume on a time scale of 5-30 min. Very rapid ouabain sensitive 22Na efflux from the vesicles is observed when ATP is photolytically released from intravesicular caged ATP.     

Dinitrophenyl glutathione efflux from human erythrocytes is primary active ATP-dependent transport.

Dinitrophenyl S-glutathione is accumulated by inside-out vesicles made from human erythrocytes in a process totally dependent on ATP and Mg2+. The vesicles were shown to accumulate dinitrophenyl S-glutathione against a concentration gradient. The vesicles were able to concentrate this glutathione derivative even in the absence of membrane potential. This indicated that the ATP-dependent uptake of dinitrophenyl S-glutathione by inside-out vesicles represented an active transport process. Neither extravesicular EGTA nor intravesicular ouabain inhibited the transport process, indicating that neither the Ca2+-ATPase nor the Na+, K+-ATPase were involved. These results indicated that dinitrophenyl S-glutathione uptake by inside-out vesicles probably represented primary active transport. The uptake of dinitrophenyl S-glutathione was a linear function of time (up to 5 h) and vesicle protein. The rate of uptake was optimal between pH 7.0 and 8.0 and at 37 degrees C. The Km values determined for dinitrophenyl S-glutathione and ATP were 0.29 mM and 1 mM, respectively. The transport process was completely inhibited by vanadate and by p-hydroxymercuribenzene sulphonate and inhibited to a lesser extent by N-ethylmaleimide. GTP could efficiently substitute for ATP as an energy source for the transport process, but CTP and UTP were comparatively much less effective.     

Altered Mg2+ transport across liver plasma membrane from streptozotocin-treated rats

Type-I diabetes is associated with a decrease in magnesium content in various tissues, including liver. We have reported that hepatocytes from streptozotocin-injected rats have lost the ability to accumulate Mg2+ following hormonal stimulation. To assess whether the defect is inherent to the Mg2+ transport mechanism located in the hepatocyte cell membrane, plasma membrane vesicles were purified from diabetic livers. Diabetic plasma membranes do not retain intravesicular Mg2+ as tightly as vesicles purified from livers of age-matched non-diabetic rats. In addition, the amount of intravesicular Mg2+ these vesicles exchange for extravesicular Na+ or Ca2+ is 2-3-fold larger than in non-diabetic vesicles. The partition of Ca2+/Mg2+ and Na+/Mg2+ exchange mechanisms in the apical and basolateral domains of liver plasma membrane is maintained under diabetic conditions, although the Na+/Mg2+ exchanger in diabetic basolateral membranes has lost the ability to operate in reverse and favor an accumulation of extravesicular Mg2+ within the vesicles in exchange for entrapped Na+. These data indicate the occurrence of a major alteration in Mg2+ transport across the hepatocyte membrane, which can explain, at least in part, the decrease in liver magnesium content observed in diabetic animals and patients.     

Matrix free Ca2+ in isolated chromaffin vesicles

Isolated secretory vesicles from bovine adrenal medulla contain 80 nmol of Ca2+ and 25 nmol of Mg2+ per milligram of protein. As determined with a Ca2+-selective electrode, a further accumulation of about 160 nmol of Ca2+/mg of protein can be attained upon addition of the Ca2+ ionophore A23187. During this process protons are released from the vesicles, in exchange for Ca2+ ions, as indicated by the decrease of the pH in the incubation medium or the release of 9-aminoacridine previously taken up by the vesicles. Intravesicular Mg2+ is not released from the vesicles by A23187, as determined by atomic emission spectroscopy. In the presence of NH4Cl, which causes the collapse of the secretory vesicle transmembrane proton gradient (delta pH), Ca2+ uptake decreases. Under these conditions A23187-mediated influx of Ca2+ and efflux of H+ cease at Ca2+ concentrations of about 4 microM. Below this concentration Ca2+ is even released from the vesicles. At the Ca2+ concentration at which no net flux of ions occurs the intravesicular matrix free Ca2+ equals the extravesicular free Ca2+. In the absence of NH4Cl we determined an intravesicular pH of 6.2. Under these conditions the Ca2+ influx ceases around 0.15 microM. From this value and the known pH across the vesicular membrane an intravesicular matrix free Ca2+ concentration of about 24 microM was calculated. This is within the same order of magnitude as the concentration of free Ca2+ in the vesicles determined in the presence of NH4Cl.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of hydrolysis of phosphorylated Ca2+,Mg2+-ATPase of the sarcoplasmic reticulum by Ca2+ inside and outside the vesicles

The effects of intra- and extravesicular calcium and magnesium ions on the hydrolysis of the phosphoenzyme (EP) intermediate formed in the reaction of Ca2+,Mg2+-dependent ATPase of the sarcoplasmic reticulum were investigated. The rate constants of EP hydrolysis were measured under conditions that allowed a single turnover of ATP hydrolysis to minimize the increase in calcium concentration inside the vesicles. The EP formed during a single turnover was hydrolyzed biphasically and could be resolved into fast- and slow-decomposing components. When free Mg2+ outside the vesicles was chelated by adding excess EDTA, EP could also be kinetically resolved into two components; EDTA-sensitive EP, which could be quickly decomposed by adding EDTA, and EDTA-insensitive EP, which could be prevented from decomposing by adding EDTA. The amount of EDTA-sensitive EP decreased rapidly during the initial phase of the reaction, while that of EDTA-insensitive EP decreased slowly with the same rate constant as that of the slow-decomposing EP. These results showed that the biphasic time course of EP hydrolysis was caused by the formation of EDTA-sensitive and -insensitive EP during the reaction. The time course of EP hydrolysis could be quantitatively analyzed in terms of the following reaction mechanism. (formula; see text) The decomposition of EDTA-insensitive EP required Mg2+ outside the vesicles and was competitively inhibited by extravesicular Ca2+. The decomposition of EDTA-sensitive EP was inhibited by Ca2+ inside the vesicles but not by external Ca2+. The linear relationships between the inverse of the rate constants of EP decomposition during the initial phase and the intravesicular CaCl2 concentrations suggested that decomposition of EDTA-sensitive EP was inhibited by the binding of 1 mol of intravesicular Ca2+ to 1 mol of EP. Furthermore, Mg2+ inside the vesicles scarcely affected the inhibition of EP hydrolysis by intravesicular Ca2+. These results suggested that magnesium ions are not counter-transported during the active transport of calcium by SR vesicles.     

Fast release of calcium from sarcoplasmic reticulum vesicles monitored by chlortetracycline fluorescence

Rapid Ca2+ release rate from sarcoplasmic reticulum vesicles was determined by the stopped flow method in terms of chlortetracycline fluorescence. Intensity of chlortetracycline fluorescence was proportional to the intravesicular free Ca2+ concentration. Ca2+ efflux was activated by extravesicular Ca2+ with an apparent dissociation constant of 25 microM and was inhibited with an inhibition constant of 120 microM in the absence of Mg2+. Caffeine enhanced the Ca2+ release rate by increasing only the affinity of Ca2+ for the activation site. Mg2+ reduced the Ca2+ release rate by competitive binding to the activation site. ATP increased the Ca2+ release rate very much without changing the affinities of Ca2+ for the activation and inhibition sites, i.e., ATP seems to increase the pore radius or number of the Ca2+ channels without affecting the gating mechanism of the channel. These results are consistent with those reported in skinned muscle sarcoplasmic reticulum. The maximum rate of Ca2+ release in the presence of ATP reached 80 s-1. This value is considered to be sufficient to cause muscular contraction.     

Ca2+ accumulation and loss by aberrant endocytic vesicles in sickle erythrocytes.

Sickle cells contain internal vesicles which accumulate Ca2+. As shown here, the membrane enclosing the vesicles contains the plasma membrane Ca(2+)-ATPase, or Ca2+ pump, as judged by staining with an antibody directed against the protein. Moreover, the number of cells containing such vesicles increases upon deoxygenation. These findings argue strongly that the vesicles arise by endocytosis from the plasma membrane, and explain how they accumulate Ca2+. When sickle cells are depleted of ATP, Ca2+ is lost from the vesicles, as judged by the disappearance of staining with the Ca2+/membrane probe chlortetracycline (CTC), without a corresponding loss of antibody staining. This loss of Ca2+ can be inhibited by nitrendipine, a Ca2+ channel blocker. These results suggest that the vesicle membrane allows outward passage of Ca2+ by a nitrendipine-sensitive pathway, which can be overcome by the inward-directed activity of the Ca2+ pump of the vesicle membrane. If so, the Ca2+ which vesicles contain is in dynamic equilibrium with the cytoplasm of the sickle erythrocyte.     

Cell-Free Transfer of Phosphatidylinositol between Membrane Fractions Isolated from Soybean

Transfer of phosphatidylinositol (PI) between membranes was reconstituted in a cell-free system using membrane fractions isolated from dark-grown soybean (Glycine max [L.] Merr.). Donor membrane vesicles contained [3H]myo-inositol-labeled PI. A fraction enriched in endoplasmic reticulum was a more efficient donor than its parent microsomal membrane fraction. As acceptor, cytoplasmic side-out plasma membrane vesicles were more efficient than cytoplasmic side-in plasma membrane vesicles. Endoplasmic reticulum was also an efficient acceptor, suggesting that transfer occurred to cytoplasmic membrane leaflets. PI transfer was time and temperature dependent but did not require cytosolic proteins, ATP, GTP, cytosol, and acyl-coenzyme A. These results suggest that neither lipid transfer proteins nor transition vesicles, similar to those involved in vesicle trafficking from endoplasmic reticulum to the Golgi apparatus, were involved. In the presence of Mg2+ and ATP, endoplasmic reticulum PI was not metabolized, whereas PI transferred to the plasma membrane was metabolized into phosphatidylinositol monophosphate and phosphatidylinositol bisphosphate. To summarize, the cell-free transfer of endoplasmic reticulum-derived PI was distinct from, for example, vesicle transport from endoplasmic reticulum to Golgi apparatus, not only in its regulation but also in its acceptor unspecificity.     

Changes in the intensity of the fluorescence of potential-sensitive fluorescent probes in the active transport of Ca2+ in the fragmented sarcoplasmic reticulum

The dependence of fluorescence intensity changes of potential-sensitive fluorescent probes 3,3'-dipropyl-2,2'-thyodicarbocianine and 1-anilino-8-naphtalenesulphonae on the ATP concentration during Ca2+ transport in fragmented SR of the rabbit skeletal muscle has been studied. An increase in the accumulation of Ca2+ in the SR vesicles caused by ATP is accompanied by an increase in the fluorescence intensity of the potential-sensitive probes. These fluorescence changes are related neither to ATP or Ca2+ effect but are coupled with cation accumulation inside the vesicles since they are not observed in the presence of either EGTA or triton X-100 or in the absence of Mg2+. The results obtained prove the membrane potential generation in SR in the course of ATP-dependent Ca2+ transport.     

Calcium/sodium exchange in purified secretory vesicles from bovine neurohypophyses

Purified secretory vesicles isolated from bovine neurohypophyses take up Na+ under the same circumstances where an efflux of Ca2+ takes place, suggesting a Na+/Ca2+ exchange. Potassium cannot substitute for Na+ in this process. Also, a Ca2+/Ca2+ exchange can occur. Inhibiting the latter process by Mg2+ allowed to estimate an apparent KM of 0.7 microM free Ca2+ and a maximal uptake of 1.5 nmol X mg protein-1 X min-1 Ca2+ in exchange for Na+. The vesicles did not contain plasma membrane marker (Na+/K+ ATPase) as shown by distribution analyses on the density gradients on which they were purified. Similarly, distribution studies also showed that no other ATPase activity could be detected in the purified vesicle fraction. It is concluded that a Na+/Ca2+ exchange is operating across the secretory vesicle membrane and that it is not directly dependent on ATP hydrolysis.     

Ca2+ gradient and drugs reveal different binding sites for Pi and Mg2+ in phosphorylation of the sarcoplasmic reticulum ATPase.

The first step towards ATP synthesis by the Ca2-ATPase of sarcoplasmic reticulum is the phosphorylation of the enzyme by Pi. Phosphoenzyme formation requires both Pi and Mg2+. At 35 degrees C, the presence of a Ca2+ gradient across the vesicle membrane increases the apparent affinity of the ATPase for Pi more than 10-fold, whereas it had no effect on the apparent affinity for Mg2+. In the absence of a Ca2+ gradient, the phosphorylation reaction is inhibited by both K+ and Na+ at all Mg2+ concentrations used. However, in the presence of 1 mM Mg2+ and of a transmembrane Ca2+ gradient, the reaction is still inhibited by Na+, but the inhibition promoted by K+ is greatly decreased. When the Mg2+ concentration is raised above 2 mM, the enzyme no longer discriminates between K+ and Na+, and the phosphorylation reaction is equally inhibited by the two cations. Trifluoperazine, ruthenium red and spermidine were found to inhibit the phosphorylation reaction by different mechanisms. In the absence of a Ca2+ gradient, trifluoperazine competes with the binding to the enzyme of both Pi and Mg2+, whereas spermidine and ruthenium red were found to compete only with Mg2+. The data presented suggest that the enzyme has different binding sites for Mg2+ and for Pi.     

Mechanism of phosphorylation in the lumen of the Golgi apparatus. Translocation of adenosine 5'-triphosphate into Golgi vesicles from rat liver and mammary gland

The occurrence of phosphorylated secretory proteins such as caseins and vitellogenin and the recent characterization of phosphorylated proteoglycans, in the xylose and protein core, has raised the question of where in the cell and how this phosphorylation occurs. Previous studies have described a casein kinase activity in the lumen of the Golgi apparatus and this organelle as the site of xylose addition to the protein core of proteoglycans. We now report the translocation in vitro of ATP into the lumen of rat liver and mammary gland Golgi vesicles which are sealed and have the same membrane topographical orientation as in vivo. The entire ATP molecule was translocated into the lumen of the Golgi vesicles; this was established by using ATP radiolabeled with tritium in the adenine and gamma-32P. Translocation was temperature dependent and saturable, with an apparent Km of 0.9 microM and Vmax of 58 pmol/mg protein/min. Preliminary evidence suggests that translocation of ATP into the vesicles' lumen is coupled to exit of AMP from the lumen. Following translocation of ATP into the lumen of the vesicles, proteins were phosphorylated.     

Energy interconversion in sarcoplasmic reticulum vesicles in the presence of Ca2+ and Sr2+ gradients

Sarcoplasmic reticulum vesicles of rabbit skeletal muscle are able to accumulate Ca2+ or Sr2+ at the expense of ATP hydrolysis. Depending on the conditions used, vesicles loaded with Ca2+ can catalyze either an ATP in equilibrium Pi exchange or the synthesis of ATP from ADP and Pi. Both reactions are impaired in vesicles loaded with Sr2+. The Sr2+ concentration required for half-maximal ATPase activity increases from 2 microM to 60-70 microM when the Mg2+ concentration is raised from 0.5 to 50 mM. The enzyme is phosphorylated by ATP in the presence of Sr2+. The steady state level of phosphoenzyme varies depending on both the Sr2+ and Mg2+ concentrations in the medium. Phosphorylation of the enzyme by Pi is inhibited by both Ca2+ and Sr2+. In the presence of 2 and 20 mM Mg2+, half-maximal inhibition is attained in the presence of 4 and 8 microM Ca2+ or in the presence of 0.24 mM and more than 2 mM Sr2+, respectively. After the addition of Sr2+, the phosphoenzyme is cleaved with two different rate constants, 0.5-1.5 s-1 and 10-18 s-1. The fraction of phosphoenzyme cleaved at a slow rate is smaller the higher the Sr2+ concentration in the medium. Ca2+ inhibition of enzyme phosphorylation by Pi is overcome by the addition of ITP. This is not observed when Ca2+ is replaced by Sr2+.     

Substrate regulation of the sarcoplasmic reticulum ATPase. Transient kinetic studies.

The rate of phosphorylation of the Ca2+-dependent ATPase of sarcoplasmic reticulum vesicles by ITP and ATP was studied using a millisecond mixing and quenching device. The rate of phosphorylation was slower when the vesicles were preincubated in a Ca2+-free medium than when preincubated with Ca2+, regardless of the substrate used and of the pH of the medium. When the vesicles were preincubated with Ca2+ at pH 7.4 an overshoot of phosphorylation was observed in the presence of ITP. The overshoot was abolished when the pH of the medium was decreased to 6.0 or when the vesicles were preincubated in a Ca2+-free medium. Using vesicles preincubated with Ca2+ the apparent Km for ITP found was 2.5 mM at pH 6.0 and 1.0 mM at pH 7.4. The Vmax observed (77 mumol g-1 s-1) did not change with the pH of the medium. Both at pH 6.0 and 7.4 the apparent Km for ATP was 3 microM when preincubated in a Ca2+-free medium. At pH 6.0 the Vmax for ATP varied from 96 to 33 mumol g-1 s-1 depending on whether the vesicles were preincubated in the presence or absence of Ca2+. At pH 7.4 the Vmax for ATP was 90 mumol g-1 s-1 in both conditions. The rate of phosphorylation of the vesicles was dependent on the relative Ca2+ and Mg2+ concentrations of the reaction medium regardless of the substrate used.     

Delta pH, H+ diffusion potentials, and Mg2+ ATPase in neurosecretory vesicles isolated from bovine neurohypophyses

The proton gradient (delta pH) and electrical potential (delta psi) across the neurosecretory vesicles were measured using the optical probes 9-aminoacridine and Oxanol VI, respectively. The addition of neurosecretory vesicles to 9-aminoacridine resulted in a rapid quenching of the dye fluorescence which was reversed when the delta pH was collapsed with ammonium chloride or K+ in the presence of nigericin. From fluorescence quenching data and the intravesicular volume, delta pH across the membrane was calculated. Mg2+ ATP caused a marked carbonyl cyanide p-trifluoromethoxyphenylhydrazone-sensitive change in the membrane potential measured using Oxanol VI (plus 100 mV inside positive), presumably due to H+ translocation across the neurosecretory vesicle membrane. Imposition of this membrane potential was responsible for the lysis of vesicles in the presence of permeant anions. The effectiveness of these anions to support lysis reflected the relative permeability of the anion which followed the order acetate greater than I- greater than Cl greater than F- greater than SO4- = isethionate = methyl sulfate. These data showed that the neurosecretory vesicles possess a membrane H+-translocating system and prompted the study of Mg2+-dependent ATPase activities in the vesicle fractions. In intact vesicles a Mg2+ ATPase appeared to be coupled to electrogenic proton translocation, since the enzyme activity was enhanced by uncoupling the electrical potential, using proton ionophores. Inhibition of this enzyme with dicyclohexylcarbodiimide also inhibited the carbonyl cyanide p-trifluoromethoxyphenylhydrazone-sensitive delta psi across the vesicle membrane caused by H+ translocation. A second Mg2+ ATPase was also found on the vesicle membranes which is sensitive to vanadate. Complete inhibition of this enzyme with vanadate had little effect on the proton ionophore-uncoupled ATPase activity or on the Mg2+ ATP-induced membrane potential change.     

A Ca2+-stimulated adenosine triphosphatase in Golgi-enriched membranes of lactating murine mammary tissue.

A membrane fraction isolated from lactating murine mammary tissue and enriched for the Golgi membrane marker enzyme galactosyltransferase exhibited Ca2+-stimulated ATPase activity (Ca-ATPase) in 20 microM-free Mg2+ and 10 microM-MgATP, with an apparent Km for Ca2+ of 0.8 microM. Exogenous calmodulin did not enhance Ca2+ stimulation, nor could Ca-ATPase activities be detected in millimolar total Mg2+ and ATP. When assayed with micromolar Mg2+ and MgATP the Ca-ATPases of skeletal-muscle sarcoplasmic reticulum and of calmodulin-enriched red blood cell plasma membranes were half-maximally activated by 0.1 microM- and 0.6 microM-Ca2+ respectively. All three Ca-ATPases were inhibited by similar micromolar concentrations of trifluoperazine, but the Golgi activity was unaffected by quercetin in concentrations which completely inhibited both the sarcoplasmic-reticulum and red-blood-cell enzymes. The results are consistent with the hypothesis that the high-affinity Ca-ATPase is responsible for the ATP-dependent Ca2+ transport exhibited by Golgi-enriched vesicles derived from lactating mammary gland [Neville, Selker, Semple & Watters (1981) J. Membr. Biol. 61, 97-105; West (1981) Biochim. Biophys. Acta 673, 374-386].