5-Hydroxytryptamine transport in cells and secretory granules from a transplantable rat insulinoma.

Mechanisms of transport of 5-hydroxytryptamine in the pancreatic B-cell were investigated by using cell suspensions and secretory granules prepared from a transplantable rat insulinoma. (1) Cells incubated with 5-hydroxy[G-3H]tryptamine at concentrations ranging from 0.1 microM to 5 mM accumulated the radioisotope principally by a simple diffusion process. The incorporated radioactivity was recovered principally as the parent molecule and was recovered predominantly in soluble protein and secretory-granule fractions prepared from the tissue. (2) Isolated granules incubated in buffered iso-osmotic medium without ATP accumulated the amine to concentrations up to 38-fold that of the medium. This process was insensitive to reserpine and occurred over a wide range of 5-hydroxytryptamine concentrations (0.075 microM-25 mM). Above 5 mM, 5-hydroxytryptamine accumulation decreased in parallel with the breakdown of the delta pH across the granule membrane. Uptake was favoured by alkaline media and was reduced by the addition of (NH4)2SO4. In both cases a close correlation was observed between uptake and the transmembrane delta pH, a finding that suggested that 5-hydroxytryptamine permeated the membrane as the free base and equilibrated across the membrane with the delta pH. Binding of 5-hydroxytryptamine to granule constituents also played a part in this process. ATP caused a further doubling of granule 5-hydroxytryptamine uptake by a process that was sensitive to reserpine (0.5 microM). Inhibitor studies suggested that amine transport in this instance was linked to the activity of the granule membrane proton-translocating ATPase. (3) It was concluded that the uptake of amines driven by proton gradients across the insulin-granule membrane could account for the accumulation in vivo of amines in the B-cell.     

Adenosine triphosphate in the bovine chromaffin granule.

1. pH and potential gradients are generated across the membranes of chromaffin granule 'ghost' by incubating them with MgATP: the inside of the 'ghosts' is positive and acid with respect to the incubation medium. 2. The pH gradient is partially dissipated by inclusion of a substrate for the catecholamine pump, or a mitochondrial uncoupling agent, but is enhanced by reserpine. 3. An imposed pH gradient leads to amine uptake by the 'ghosts': a potential gradient leads to ATP uptake. Studies with inhibitors confirm that amine accumulation by chromaffin granules is dependent on the former, and that ATP uptake results from ATPase-induced potential difference generation. 4. ATP has two known roles in chromaffin granule structure: the first is as a substrate for a membrane-bound proton-translocating ATPase; the second is as a component of the intragranular catecholamine storage complex.     

Characterization of native and reconstituted hydrogen ion pumping adenosinetriphosphatase of chromaffin granules

The ATP-dependent H+ pump from adrenal chromaffin granules is, like the platelet-dense granule H+ pump, essentially insensitive to the mitochondrial ATPase inhibitors sodium azide, efrapeptin, and oligomycin and also insensitive to vanadate and ouabain, agents that inhibit the Na+,K+-ATPase. The chromaffin granule H+ pump is, however, sensitive to low concentrations of NEM (N-ethylmaleimide) and Nbd-Cl (7-chloro-4-nitro-2,1,3-benzoxadiazole). These transport ATPases may thus belong to a new class of ATP-dependent ion pumps distinct from F1F0-and phosphoenzyme-type ATPases. Comparisons of ATP hydrolysis with ATP-dependent serotonin transport suggest that approximately 80% of the ATPase activity in purified chromaffin granule membranes is coupled to H+ pumping. Most of the remaining ATPase activity is due to contaminating mitochondrial ATPase and Na+,K+-ATPase. When extracted with cholate and octyl glucoside, the H+ pump is solubilized in a monodisperse form that retains NEM-sensitive ATPase activity. When reconstituted into proteoliposomes with crude brain phospholipid, the extracted enzyme recovers ATP-dependent H+ pumping, which shows the same inhibitor sensitivity and nucleotide dependence as the native pump. These data demonstrate that the predominant ATP hydrolase of chromaffin granule membrane is also responsible for ATP-driven amine transport and granule acidification in both native and reconstituted membranes.     

ATP-dependent uptake of 5-hydroxytryptamine by secretory granules isolated from thyroid parafollicular cells.

The current study was done to test the hypotheses that parafollicular granules contain a vacuolar ATPase (V-ATPase) similar to that found in chromaffin granules, that the transport of H+ into granules mediated by this enzyme drives the granular uptake of 5-hydroxytryptamine (5-HT, serotonin), and that secretagogues stimulate both the acidification of parafollicular granules and their ability to take up 5-HT by opening an anion channel in the granular membrane. Our studies indicate that parafollicular granules contain a V-ATPase that is antigenically similar to that of the V-ATPase of adrenal chromaffin granules; however, the parafollicular granular membrane differs from that of chromaffin granules in permeability to Cl- and K+. The membranes of granules derived from resting parafollicular cells appear to be relatively impermeable to Cl- but permeable to K+. Parafollicular granules (and ghosts derived from them) manifest ATP-dependent transmembrane transport of 5-HT. This transport is more dependent on the pH difference (delta pH) than on the membrane potential component of the proton electrochemical gradient across the granular membrane. Transport of 5-HT is thus inhibited more by exposure of parafollicular granules to agents, such as nigericin, that collapse delta pH than by those, such as valinomycin, that decrease transmembrane difference in potential. ATP-dependent uptake of 5-HT by granules isolated from secretagogue-stimulated parafollicular cells is greater than that into granules isolated from unstimulated cells. Since secretagogues open a Cl- channel in parafollicular granule membranes, which enhances acidification of the granules, the facilitation of 5-HT uptake by secretagogues is probably due to an increase in delta pH.     

Proton-translocating adenosine triphosphatase of chromaffin-granule membranes. The active site is in the largest (70 kDa) subunit.

The proton-translocating adenosine triphosphatase (ATPase) of bovine chromaffin granules contains up to five different polypeptides. Its activity is inhibited by N-ethylmaleimide, and ATP protects the enzyme from inhibition. After treatment of membranes with N-[2-3H]ethylmaleimide, only one polypeptide is strongly radiolabelled: this is the largest (70 kDa) subunit of the proton-translocating ATPase. This subunit therefore contains the ATP-hydrolysing site. Two-dimensional electrophoresis reveals heterogeneity in this polypeptide.     

Ca2+ and proton transport in chromaffin granule membranes: a proton NMR study

High-resolution proton NMR spectroscopy has been used to monitor the internal pH of chromaffin granule ghosts during Ca2+ influx through the membrane. For this purpose, ghosts were prepared by lysing and resealing chromaffin granules in a medium containing the disodium-ethylenediaminetetraacetic acid complex (Na2.EDTA). Uncomplexed EDTA and Ca.EDTA give rise to distinct sets of methylene peaks in the proton NMR spectrum. Free EDTA titrates with a pK near 6.6 in deuterated media; the chemical shifts that accompany titration have been used to monitor intravesicular pH changes which occur inside chromaffin granule ghosts as a result of ATPase activity and deprotonation of EDTA during Ca2+ influx and complex formation. ATPase activity results in an NMR-detectable proton gradient which is dissipated by nigericin. Experiments monitoring Ca2+ uptake showed that protons which are liberated inside ghosts as a result of Ca.EDTA complex formation are not extruded from the ghosts via a process coupled to Ca2+ entry. This suggests that the Ca2+ transport system of the chromaffin granule membrane occurs without concurrent proton antiport and is not directly coupled energetically to the transmembrane pH gradient.     

H+ ATPase of chromaffin granules. Kinetics, regulation, and stoichiometry

The chromaffin granule ATPase mediates an inwardly directed transport of H+ against concentration gradients, thereby forming and maintaining an electrochemical transmembrane H+ gradient. The kinetics of this ATPase, its activity modulation by changes in electrochemical H+ gradients, and the stoichiometry between H+ transport and ATP hydrolysis were studied in intact bovine chromaffin granules, resealed chromaffin granule ghosts, and highly purified fragmented chromaffin granule membranes. In fragmented membranes the H+ ATPase has a KM for ATP of 69 microM, a maximum of activity at pH 7.3, and a Vmax of 111 nmol/min/mg of protein at 20 degrees C. Trimethyl tin inhibits the ATPase at much lower concentrations than dicyclohexylcarbodiimide, whereas oligomycin, reserpine, and other inhibitors were without effect. In intact chromaffin granules, the ATPase activity was stimulated up to 300% by collapsing the H+ transmembrane gradients. H+/ATP stoichiometry was measured in resealed chromaffin ghosts devoid of ATP and catecholamines under conditions where no net pH changes occur upon ATP hydrolysis. After addition of ATP, the rates of H+ accumulation in the ghosts and ATP hydrolysis were both linear for about 60-100 s, and the ratio of H+ to ATP was 1.71. These data indicate that the H+ ATPase of chromaffin granules has both kinetic similarities and dissimilarities with other known H+ ATPases. The regulation by changes in H+ gradients and the fixed H+/ATP ratio of this ATPase is further evidence of its primary role in establishing electrogenic H+ translocation and H+ gradients in chromaffin granules.     

The Distribution of Mg2+ ATPase and Its Loss of Specific Activity upon Gradient Centrifugation of Isolated Chromaffin Granules

Preparations of purified chromaffin granules were subjected to isopycnic sucrose gradient centrifugation. Determination of Mg2+ ATPase activity and catecholamines showed that the distribution of ATPase almost parallelled the distribution of catecholamines. The distribution of ATPase was slightly shifted to lower densities and was suggested to be caused by the heterogeneity of the chromaffin granules. The results therefore provide evidence that ATPase is associated with chromaffin granules. Determination of the recovery of ATPase activity upon gradient centrifugation revealed losses of enzyme activity which were found to be proportional to the dilutions of the granule preparation subjected to gradient centrifugation.     

Passive ion permeability of the chromaffin-granule membrane.

'Ghosts' of bovine chromaffin granules, in which the complex mixture of proteins and solutes normally found in the granule matrix is replaced by buffered sucrose are osmotically sensitive. They shrink when the osmotic pressure of the suspension medium is increased, and swell if solute entry is facilitated by the addition of ionophores. Swelling in the presence of ionophores has been used to investigate the passive ion permeability of these membranes. They have a very low permeability to K+ ions (of the order of 10(-10) cm/s); their permeability to protons, Na+ and choline ions is too low to be detected by these methods. Their passive permeability to anions decreases in the order: CNS- greater than I- greater than CCl3CO2- greater than Br- greater than Cl- greater than SO4(2)- greater than CH3CO2-, HCO3-, F-, PO4(3)- the permeability to hiocyanate being of the order of 10(-7) cm/s. Coupled proton and anion entry is extremely slow, except for weak acids. Fluoride, unexpectedly, also appears to enter rapidly when proton/K+ exchange is facilitated by nigericin. In the presence of K+ salts, nigericin, like valinomycin, induces lysis of intact granules, an effect that is not dependent on the presence of a permeant anion, but is dependent on the pH gradient across the membrane.     

Spectrophotometric measurements of transmembrane potential and pH gradients in chromaffin granules

The electrical potential (delta psi) and proton gradient (alpha pH) across the membranes of isolated bovine chromaffin granules and ghosts were simultaneously and quantitatively measured by using the membrane- permeable dyes 3,3'dipropyl-2,2'thiadicarbocyanine (diS-C3-(5)) to measure delta psi and 9-aminoacridine or atebrin to measure delta pH. Increases or decreases in the delta psi across the granular membrane could be monitored by fluorescence or transmittance changes of diS-C3- (5). Calibration of the delta psi was achieved by utilization of the endogenous K+ and H+ gradients, and valinomycin or carbonyl cyanide-p- trifluoromethoxyphenylhydrazone (FCCP), respectively, with the optical response of diS-C3-(5) varying linearly with the Nernst potential for H+ and K+ over the range -60 to +90 mV. The addition of chromaffin granules to a medium including 9-aminoacridine or atebrin resulted in a rapid quenching of the dye fluorescence, which could be reversed by agents known to cause collapse of pH gradients. From the magnitude of the quenching and the intragranular water space, it was possible to calculate the magnitude of the alpha pH across the chromaffin granule membrane. The time-course of the potential-dependent transmittance response of diS-C3-(5) and the delta pH-dependent fluorescence of the acridine dyes were studied simultaneously and quantitatively by using intact and ghost granules under a wide variety of experimental conditions. These results suggest that membrane-permeable dyes provide an accurate method for the kinetic measurement of delta pH and delta psi in an amine containing subcellular organelle.     

Ion permeability of isolated chromaffin granules.

The passive ion permeability, regulation of volume, and internal pH of isolated bovine chromaffin granules were studied by radiochemical, potentiometric, gravimetric, and spectrophotometric techniques. Chromaffin granules behave as perfect osmometers between 340 and 1,000 mosM in choline chloride, NaCl, and KCl as measured by changes in absorbance at 430 nm or from intragranular water measurements using 3H2O and [14C]polydextran. By suspending chromaffin granules in iso-osmotic media of various metal ions and selectively increasing the permeability to either the cation or the anion by intrinsically permeable ions or specific ionophores, it was possible to determine by turbidity and potentiometric measurements the permeability to the counterion. These measurements indicate that the chromaffin granule is impermeable to the cations tested (Na+, K+, and H+). Limited H+ permeability across the chromaffin granule membrane was also shown by means of the time course of pH re-equilibration after pulsed pH changes in the surrounding media. The measurement of [14C]methylamine distribution indicates that a significant deltapH exists across the membrane, inside acidic, which at an external value of 6.85 has a value of 1.16. The deltapH is relatively insensitive to changes in the composition of the external media and can be enhanced or collapsed by the addition of ionophores and uncouplers. Measurement at various values of external pH indicates an internal pH of 5.5. Use of the ionophore A23187 indicates that Ca++ and Mg++ can be accumulated against an apparent concentration gradient with calcium uptake exceeding 50 nmol/mg of protein at saturation. These measurements also show that Ca++ and Mg++ are impermeable. Measurement of catecholamine release under conditions where intravesicular calcium accumulation is maximal indicates that catecholamine release does not occur. The physiological significance of the high impermeability to ions and the existence of a large deltapH are discussed in terms of regulation of uptake, storage, and release of catecholamines in chromaffin granules.     

Uptake of Magnesium by Chromaffin Granules In Vitro: Role of the Proton Electrochemical Gradient

Abstract: The chromaffin granule membrane in vitro is impermeable to protons as well as to Mg²⁺; however, when granules are incubated in the presence of the proton ionophore carbonyl cyanide p -trifluoromethoxy-phenylhydrazone or an inhibitor of the granule membrane Mg²⁺-dependent ATPase, the metal ion is accumulated inside the granules. This accumulation is dependent upon the granule transmembrane potential. The simultaneous presence of the ATPase inhibitor and the proton ionophore markedly increases metal ion incorporation. Mg²⁺ incorporation is also promoted by nigericin in the presence of potassium or sodium ions, indicating that Mg²⁺ accumulation is also dependent upon the transmembrane pH gradient. Concomitant with the Mg²⁺ accumulation, there is a significant loss of endogenous catecholamines. It is concluded that Mg²⁺ accumulation is determined by the electrochemical gradient maintained across the membrane. Once the metal ion has accumulated into the granules it displaces catecholamines from their storage sites.     

The assignment of the Ca2+-ATPase activity of chromaffin granules to the proton translocating ATPase

CaATP is shown to function as a substrate for the proton translocating ATPase of chromaffin granule ghosts at concentrations which are comparable to that of MgATP. Using the initial rate of the proton pump activity as the measure (delta pH/delta t), an apparent Km-value of 139 +/- 8 microM was estimated for CaATP and 59 +/- 3 microM for MgATP. The maximal rate was markedly higher with MgATP than with CaATP, partly due to an inhibition of the hydrolytic activity at the higher concentrations of CaATP. The proton pump activity with CaATP was inhibited by N-ethylmaleimide and N,N'-dicyclohexylcarbodiimide at concentrations similar to that found for MgATP. No inhibition was observed with sodium vanadate in the concentration range 0-15 microM. Calmodulin and trifluoperazine had no effect on the overall ATPase activity with CaATP. These findings establish this activity as an intrinsic property of the chromaffin granules, i.e., linked to the H+-ATPase. No evidence was obtained for the presence of a Ca2+-translocating ATPase [Ca2+ + Mg2+)-ATPase) in the chromaffin granules.     

Membrane and soluble proteins of adrenal chromaffin granules

Bovine adrenal chromaffin granules are useful 'model' neurosecretory vesicles, particularly for biochemical studies. The granule matrix contains three major secretory proteins (chromogranin A and secretogranins I and II) together with peptides derived from them, and smaller amounts of neuropeptides (enkephalins and neuropeptide Y). Several different endo- and exo-proteinases are also present in both soluble and membrane-bound forms. The major membrane proteins are those involved in catecholamine biosynthesis (dopamine beta-monooxygenase and cytochrome b(561)), active transport of granule components (vacuolar-type proton-translocating ATPase, and carriers for monoamines, nucleotides and small ions) and exocytosis (synaptotagmin, synaptobrevin and other proteins). In addition, the functions of a number of major granule membrane proteins remain unknown.     

Existence of an adenosine 5'-triphosphate dependent proton translocase in bovine neurosecretory granule membrane

The addition of ATP to bovine neurohypophysial secretory granules suspended in isotonic sucrose medium induces a positive polarization, delta psi, of their interior without affecting their internal pH. In KCl-containing media, ATP failed to generate large delta psi but induced a pH gradient (delta pH; interior acidic). These observations are consistent with the existence in the neurosecretory granule membrane of an ATP-dependent inward electrogenic H+ translocase (H+ pump), capable in KCl-containing media of acidifying the granule matrix by H+-Cl- cotransport. The delta psi and delta pH generated by the H+ pump, defined as the ATP-induced changes sensitive to the H+ ionophore carbonyl cyanide m-chlorophenylhydrazone (CCCP), were blocked by N,N'-dicyclohexylcarbodiimide, an inhibitor of all H+ pumps, and were insensitive to oligomycin, a mitochondrial ATPase inhibitor. In sucrose medium, measurements were complicated by a Donnan equilibrium reflecting the presence in the granule of peptide hormones and neurophysins which resulted in a CCCP-resistant resting delta pH. In KCl-containing media, the Donnan equilibrium was destroyed since the membrane is permeable to cations, but under these conditions a CCCP-resistant K+-diffusion potential was observed. The ATP-induced delta psi was also monitored by the extrinsic fluorescent probe bis(3-phenyl-5-oxoisoxazol-4-yl)pentamethine oxonol. The hypothesis of a granule H+ pump is further supported by the presence of an oligomycin-resistant ATPase in the preparation and the ultrastructural localization of such an activity on the granule membrane. The H+ pump has been found in both newly formed and aged neurosecretory granules. Its possible physiological function is discussed with reference to that of chromaffin granules, with which it has many similarities.     

Solubilization and reconstitution of the catecholamine transporter from bovine chromaffin granules.

The catecholamine transporter from bovine chromaffin granules has been solubilized by using low concentrations of sodium cholate in the presence of phospholipids. The functional solubilized protein has been incorporated into liposomes after removal of the detergent either by gel filtration or by dialysis. Reserpine-sensitive accumulation against a concentration gradient is achieved by artifically imposing a pH gradient across the membrane. In the reconstituted system adenosine 5'-triphosphate (ATP) serves as an energy source only at higher detergent concentrations. The proton-translocating adenosine triphosphatase (ATPase) is solubilized in parallel with the increasing efficiency of ATP as an energy source. Several criteria are proposed to distinguish between carrier-mediated (reserpine sensitive) and unmediated transport in the reconstituted system. The reserpine-sensitive process shows affinity and ss presented in this communication provide further support for the contention that concentrative uptake in biogenic amine storage vesicles is driven by a transmembrane pH gradient, which, in the native system, is generated by a proton-translocating ATPase. Moreover, the assays described provide a tool for the isolation and purification of the transport protein.     

Biochemical and immunological evidence for a calcium pump in chromaffin granules

ATP stimulated the accumulation of 45Ca2+ by chromaffin granule ghosts which contained 5 mM oxalate to trap transported calcium within the lumen. Inasmuch as the ATP-dependent 45Ca2+ transport was resistant to 25 mM ammonium acetate as well as the proton ionophore, carbonylcyanide-m-chlorophenylhydrazone, the chromaffin granule proton translocating ATPase does not provide the energy for this process. Instead, we suggest that chromaffin granules contain a calcium translocating ATPase which catalyzes the 45Ca2+ uptake directly. The observation that chromaffin granules bind to a monoclonal antibody raised against a calcium pump from bovine brain supports this hypothesis.     

Relative lack of ATP-driven H+ translocase activity in isolated parotid secretory granules

The possible presence of ATP-driven H+ translocase activity in isolated rat parotid secretory granules has been examined by several approaches. First the transmembrane pH difference measured by either [14C] methylamine or [3H]acetate distribution is not substantially affected by ATP in the presence of membrane-permeating anions. Second, despite a low intrinsic H+ permeability of parotid granule membranes, only a small variably detectable inside-positive transmembrane potential is observed (by altered distribution of radioactive ions) when ATP is added in the absence of permeant anions. Third, ATP-induced lysis of parotid granules is minor and appears to be independent of ATP hydrolysis. Finally, ATP-hydrolase activity of the parotid granule fraction is not stimulated by an H+ ionophore, nor is it susceptible to inhibition by 7-chloro-4-nitrobenz-2-oxa-1,3-diazole at a concentration which decreases the measured ATPase of purified chromaffin granule membranes by more than 80%. These findings suggest that this exocrine secretory granule type, which is characterized by storage of a heterogeneous mixture of secretory proteins, exhibits H+ pump activity which is at most a small fraction of that observed in biogenic amine storage granules of neural and endocrine tissues.     

Chromaffin granule-cytoskeleton interaction. Stabilization by F-actin of ATPase in purified chromaffin granule membranes

The influence of cytoskeletal elements on the chromaffin granule function was studied using a model system consisting of purified granule membranes and F-actin. The membrane ATPase was partially inactivated by incubation at 37 degrees C, and this inactivation was prevented by adding F-actin. The stabilizing action of F-actin on the ATPase was abolished by adding DNase I. Detergent-solubilized ATPase was more rapidly and profoundly inactivated, but was not stabilized by F-actin. The stabilization of ATPase by F-actin may be due to the cross-linking of granule membranes with F-actin and the native structure of the granule membrane may be required for preserving the stability of membrane ATPase. These findings thus suggest the possibility that the interaction of microfilaments with chromaffin granules may influence the function of chromaffin granules within the cell.     

ATP-driven proton fluxes across membranes of secretory organelles

The ATP-dependent proton uptake by chromaffin granule membranes, lysosomes, and synaptosomes was examined. In synaptosomes the reaction was absolutely dependent on the presence of chloride, while in chromaffin granules chloride had a profound effect and in lysosomes only a minor effect. The presence of chloride markedly increases the rate of collapse of delta pH by carbonyl cyanide p-trifluoromethoxyphenylhydrazone in all three organelles. Ascorbate with phenazine methosulfate uncoupled the ATP-dependent proton uptake by chromaffin granules, but had no effect on lysosomes and synaptosomes. Proton uptake by submitochondrial particles was about 50-fold more sensitive to dicyclohexylcarbodiimide than the proton uptake by chromaffin granule membranes. Chromaffin granule membranes were treated with 2 M sodium bromide to inactivate the mitochondrial ATPase. The treatment caused a complete inhibition of the ATP-dependent proton uptake. Solubilization of these membranes by sodium cholate, followed by reconstitution by cholate dilution revealed the ATP-dependent proton uptake of the system. It is concluded that the genuine ATPase enzyme of chromaffin granules is a proton translocator.