Characterization of phospholipase activities in chromaffin granule ghosts isolated from the bovine adrenal medulla

Energy-dependent accumulation of calcium antagonists in catecholamine storage vesicles

The calcium antagonists verapamil, nitrendipine, mibefradil, and amlodipine accumulate in chromaffin granule ghosts with apparent equilibrium partition coefficients [(mol/mg membrane lipid)/(mol/mg solvent water)] of 246 +/- 105 (N = 8), 2700 +/- 600 (N = 4), 7400 +/- 2200 (N = 4), and 8100 +/- 1100 (N = 5), respectively. In the presence of 1.2 mM MgATP, the partition coefficients were 854 +/- 206 (N = 10), 2300 +/- 600 (N = 4), 32,700 +/- 8,900 (N = 7), and 20,300 +/- 5,000 (N = 11) for verapamil, nitrendipine, mibefradil, and amlodipine, respectively. Except for nitrendipine, the apparent partition coefficients in the presence of MgATP were significantly different from the control (P < 0.001). For amlodipine and verapamil, the vacuolar H(+)-ATPase inhibitors bafilomycin A1 (30 nM) and N-ethylmaleimide (2 mM) and the protonophore (uncoupler) carbonyl cyanide m-chlorophenylhydrazone (CCCP, 10 microM) completely blocked the increase in partition coefficients in response to MgATP. The extra amlodipine, mibefradil, and verapamil that accumulated in response to MgATP were released into the medium by CCCP (10 microM) by 18% (N = 5), 30% (N = 5), and 88% (N = 5) for amlodipine, mibefradil, and verapamil, respectively. Thus, amlodipine, mibefradil, and verapamil, but not nitrendipine, accumulate in catecholamine storage vesicles in response to delta mu H+ generated by the endogenous V-type H(+)-ATPase, and are partially released by de-energetisation. Hence, these calcium antagonists can reach unexpectedly high concentrations in certain target cells, and give pharmacodynamic properties not shared by nitrendipine.

Identification and characterization of carboxyl ester hydrolase as a phospholipid hydrolyzing enzyme of zymogen granule membranes from rat exocrine pancreas

Salt-washed (0.6 m NaCl) zymogen granule membranes (ZGM) of rat pancreatic acinar cells were utilized to identify and characterize membrane protein(s) responsible for phospholipase and lysophospholipase activities. Five major bands were identified in salt-washed ZGM by Coomassie Brilliant Blue. A 70-kDa protein with enzymatic activity was retained in significant quantities after several washes with 0.6 M NaCl but could be displaced from ZGM by 2 m NaCl or by 100 mg/ml heparin. By contrast, GP2, an integral membrane protein, was not displaced under these conditions. These findings suggest that the enzyme is a peripheral membrane protein of ZGM. Renaturation of ZGM proteins following electrophoresis revealed that the 70-kDa protein possessed phospholipase activity. Identification of the 70-kDa protein as a membrane-associated carboxyl ester hydrolase was based upon: (a) the use of a specific polyclonal antiserum, (b) N-terminal sequence, (c) two-dimensional gel analysis, (d) enzymatic characterization, and (e) co-localization to an area of a non-reducing gel containing significant phospholipase activity. Other ZGM proteins, namely GP2 and GP3, could not be demonstrated to possess phospholipase activity under the experimental conditions employed. Our finding that carboxyl ester hydrolase from ZGM exhibits PLA1 and lysophospholipase activities represents the first identification and characterization of a protein responsible for phospholipase activity in secretory granule membranes.

The presence of phospholipase A2 in bovine adrenal medulla: arguments for more than one type of phospholipase A2

Since phospholipase A2 (PLA2) is expected to play a role in the mechanism of exocytosis, the presence and subcellular localization of PLA2 in bovine adrenal medulla have been studied. The results of this study reveal that, although a large part of the PLA2 activity in chromaffin cells is due to a lysosomal PLA2, a cytoplasmic PLA2 is also present. This finding is supported by experiments in which the influence of pH, CaCl2 and NaCl on cytoplasmic PLA2 as well as the binding capacity to concanavalin A are investigated. According to these results the properties of a cytoplasmic PLA2 are clearly different from those reported by other authors for the lysosomal PLA2. For this reason, in chromaffin cells a PLA2 could be present which remains in the cytosol when the cell is in rest. Future experiments will have to prove whether this PLA2 becomes associated with the plasma membrane upon stimulation of the cell, thus mediating exocytosis.

Biomembrane-modulated, lysosomal phospholipase A2 contamination of chromaffin granule ghosts

It was reported that subcellular fractionation of bovine adrenal medulla results in the separation of distinct, non-calcium-dependent phospholipases A2--one associated with chromaffin granule ghosts, another with lysosomes. The basis of this distinction is pH optimum: in routine assays utilizing neat liposomal substrates, the chromaffin granule ghost-associated enzyme is alkaline-active whereas the lysosomal enzyme is acid-active (Husebye, E.S. and Flatmark, T. (1987) Biochim. Biophys. Acta 920, 120-130). We now report that biomembranes after liposomal substrates and/or lysosomal phospholipase A2 such that the enzyme now hydrolyzes them (at low cation concentration) with an alkaline pH optimum. In a lysosomal membrane fraction, phospholipase A2 activity at pH 7.5 relative to activity at pH 5.0 increases as increasing amounts of lysosomal membranes are assayed. The pH optimum of chromaffin granule ghost-associated phospholipase A2 toward liposomal substrates is likewise biomembrane-dependent and, when assayed carefully, is indistinguishable on the basis of optimal pH from the lysosomal enzyme. Although chromaffin granule ghost-associated phospholipase A2 is most likely a lysosomal contaminant, its broad, biomembrane-modulated pH range may still allow it to participate in catecholamine secretion. More importantly, however, sensitivity of adrenal medullary lysosomal phospholipase A2 to biomembranes broadens its potential physiologic pH range and may also play a role in the regulation of this potentially deleterious activity.

Characterization of phospholipase A2 and acyltransferase activities in purified zymogen granule membranes

Phospholipase A2 and acyltransferase activities were identified in membranes associated with purified pancreatic zymogen granules. In homogenate and granule membranes, phospholipase activity was linearly related to protein concentration and was Ca2(+)-dependent with an alkaline pH optimum. The Ca2+ sensitivity was observed over the range of concentrations through which intracellular ionic Ca2+ is elevated by physiological stimuli in intact cells. Intact zymogen granules and granule membranes also demonstrated reacylating activity in the presence and absence of an exogenous acceptor. Reacylating activity was related to the concentration of lyosphospholipid added and was optimally activated at alkaline pH. A more rapid rate of reacylation was observed when [14C]arachidonoyl CoA was employed as the donor molecule rather than [3H]arachidonate (plus coenzyme A); this suggests the absence of acyl-CoA synthetase in the purified granule membranes. We conclude that granule membrane phospholipase A2 and acyltransferases may be involved in arachidonic acid turnover in exocrine pancreas and perhaps in membrane fusion events associated with exocytosis.

Fusion of neurotransmitter vesicles with target membrane is calcium independent in a cell-free system

In adrenal chromaffin cells, stimulation of Ca2+ influx leads to the secretion of neurotransmitters. The intracellular Ca2+ target involved in the fusion of secretory vesicles with the plasma membrane (PM) is still not known. We have reconstituted this fusion in vitro by using chromaffin granules (CGs) and target membrane vesicles and a Ca2(+)-dependent phospholipase A2 (PLA2). Vesicle fusion is measured by a fluorescence dequenching assay with octadecyl rhodamine B used as the marker. CGs fuse with PM vesicles only in the presence of active PLA2. The kinetics of this fusion process depend on the amount of target PM added. Once fusion competence of PM vesicles is achieved by exposure to PLA2 (primed PM vesicles), it is conserved after removal of the PLA2 even in Ca2(+)-free buffer. The kinetics of fusion between these primed PM vesicles and CGs depend on the amount of PM and on the temperature. Further incubation of the PLA2-treated PM vesicles at 30 degrees C in the absence of calcium results in an enhanced fusion competence. During this incubation, the amount of free arachidonic acid liberated by PLA2 decreases, suggesting that during a second process arachidonic acid may be processed to the terminal fusogen. The final steps of secretion can thus be subdivided into a Ca2(+)-dependent and -independent process: first, a Ca2(+)-dependent activation of PLA2 liberating fatty acids from phospholipids and second, a Ca2(+)-independent processing to the terminal fusogen and subsequent Ca2(+)-independent fusion of the CGs with the PM.

Characterization and partial purification of soluble, lysosomal phospholipase(s) A2 from adrenal medulla

Soluble, cation-dependent, lysosomal phospholipase A2 in bovine adrenal medulla has been biochemically characterized and partially purified, and its unique pH-dependent modulation by cations has been investigated. Chromatographically distinct activities with somewhat broad pI ranges centered at 7.8, 8.1, and 8.4 have been purified 83-, 1900- and 4400-fold, respectively, from the soluble fraction of tissue homogenates. With a specific activity of 4.2 mumol phospholipid hydrolyzed per mg protein per min, the fraction of pI 8.4 is the most highly purified lysosomal phospholipase A2 reported to date; yet silver staining of isoelectric focusing gels indicates that all three species are still only minor components of the protein mixtures with which they co-purify. Lysosomal phospholipase(s) A2 has an apparent molecular weight of 30,600, as determined by gel permeation chromatography; and is probably an oligomannose-containing glycoprotein as indicated by binding to concanavalin A-Sepharose and elution by methyl alpha-D-mannopyranoside. Cation concentrations modulate hydrolysis of biomembranous phospholipid, but not neat liposomal phospholipids, in a complex manner over a broad pH range (pH 4.0-8.0). Triton X-100 stabilizes the enzyme(s) but is inhibitory when present during assay; consequently, detergent-phospholipid mixed micelles are poor substrates. Thus, experimental results are dramatically dependent on the physicochemical nature of the substrate. The role of this phospholipase(s) A2 in the membrane fusion and lysis events of catecholamine secretion, as well as its regulation by cellular proteins, can now be investigated utilizing this partially purified enzyme(s).

Phosphatidylinositol kinase of bovine adrenal chromaffin granules. Modulation by hydrophilic and amphiphilic cations

The effects of hydrophilic and amphiphilic cations on the activity of phosphatidylinositol (PI) kinase (EC 2.7.1.67) of chromaffin granule ghosts were investigated. The cations studied can be divided into two groups, i.e. (i) compounds with a biphasic response (stimulation and inhibition), and (ii) those with a selective stimulatory effect on the enzyme activity. The cationic amphiphile trifluoperazine belongs to the first group, and stimulated the enzyme activity, maximal at 80 microM (2-fold), with a progressive inhibition at higher concentrations. This biphasic response was shared by a number of structurally related cationic amphiphiles, i.e. the tricyclic antidepressants, imipramine and desipramine, the phenothiazine, chlorpromazine, the miconazole derivative, calmidazolium, the beta-adrenergic agonist, propranolol, compound 48/80, as well as by the hydrophilic cations neomycin and poly-L-lysine. On the other hand, a pure stimulatory effect was observed with the amphiphilic polypeptide mastoparan and the polycationic compound spermidine, whereas ACTH1-39 and ACTH1-24 (peptides structurally related to mastoparan) revealed a slight inhibitory effect. We conclude that all the cations tested including Mg2+, stimulate PI kinase activity rather unspecifically by binding of the positively charged groups to a membrane component, probably the PI kinase itself. This site is different from that mediating the specific inhibition by calcium (Husebye ES and Flatmark T, Biochim Biophys Acta 968: 261-265, 1988). The inhibitory effect of cationic amphiphiles is correlated to their lipid solubility, and represents a perturbation of the membrane structure, but not a solubilization of enzyme or phosphoinositide from the membrane. The inhibitory effect of hydrophilic cations is due to complexation of ATP.

Phosphatidylinositol kinase of bovine adrenal chromaffin granules: kinetic properties and inhibition by low concentrations of Ca2+

The kinetics and regulatory properties of phosphatidylinositol (PI) kinase were studied in chromaffin granule ghosts isolated from the bovine adrenal medulla. Phosphatidylinositol 4-phosphate (PIP) was the major 32P-labelled phospholipid formed when the isolated membranes were phosphorylated by [gamma-32P]ATP. The PI kinase activity was rather independent of pH, but highly dependent on Mg2+ with a maximal stimulation at 60 mM Mg2+. By contrast, KCl and NaCl had a slight inhibitory effect. The Km value for MgATP was 44 and 62 microM in the presence of 1 and 20 mM MgCl2, respectively. The PI kinase was almost fully and reversibly inhibited by free Ca2+ (calmodulin-independent) in the nanomolar and low micromolar range, depending on the concentration of Mg2+. The inhibition was not dependent on Ca2+-stimulated protein phosphorylation, and it could not be explained by a dephosphorylation of PIP.