Ascorbic acid within chromaffin granules. In situ kinetics of norepinephrine biosynthesis

Ascorbic acid requirements for norepinephrine biosynthesis were investigated in intact bovine chromaffin granules using the physiologic substrate dopamine and a novel coulometric electrochemical detection high pressure liquid chromatography system for ascorbic acid. 10 mM external dopamine, 1 mM Mg-ATP, and 1 mM ascorbic acid produced maximal norepinephrine biosynthesis without granule lysis. When external ascorbic acid was omitted, intragranular ascorbic acid was consumed in a 1:1 ratio with respect to norepinephrine biosynthesis. The initial concentration of intragranular ascorbic acid was 10.5 mM, which was depleted in stepwise fashion to 15 lower concentrations over the range of 9.2-0.2 mM. Chromaffin granules containing these varying concentrations of intragranular ascorbic acid were then incubated with 1 mM exogenous ascorbic acid, and norepinephrine biosynthesis from dopamine was determined. The apparent Km of norepinephrine biosynthesis for intragranular ascorbic acid was 0.57 mM by Eadie-Hofstee analysis and 0.68 mM by Lineweaver-Burk analysis. These data indicate that intragranular ascorbic acid is available and required for norepinephrine biosynthesis, that ascorbic acid is a true co-substrate for dopamine beta-monooxygenase, and that intragranular ascorbic acid is maintained by extragranular ascorbic acid. Continued norepinephrine biosynthesis in granules is dependent on both intragranular and extragranular concentrations of the vitamin. Furthermore, in situ kinetics of dopamine beta-monooxygenase for ascorbic acid may be most accurately determined using intact granules and the true physiologic substrate.     

Ascorbic acid regeneration in chromaffin granules. In situ kinetics.

We have investigated in intact chromaffin secretory vesicles the kinetics, specificity, and mechanism of intragranular ascorbic acid regeneration by extragranular ascorbic acid. The apparent Km of internal ascorbic acid regeneration for external ascorbic acid was 280 microM by Lineweaver-Burk analysis and 287 microM by Eadie-Hofstee analysis. Intragranular ascorbic acid regeneration was specifically mediated by extragranular ascorbic acid or its isomer isoascorbic acid; the reducing agents glutathione, thiourea, homocysteine, NADH, and NADPH did not support regeneration. The structural analog D-glucose did not inhibit regeneration by external ascorbic acid, suggesting specificity at the membrane site of electron transfer. The driving force for regeneration of intragranular ascorbic acid was independent of membrane potential, absolute intragranular and extragranular pH, and ATPase activity, but might be coupled to the pH difference across the chromaffin granule membrane. Since the apparent Km of regeneration was approximately 10-fold below the cytosolic concentration of ascorbic acid, the reaction may proceed at Vmax in situ.     

Evidence for an ascorbate shuttle for the transfer of reducing equivalents across chromaffin granule membranes

Adrenal chromaffin granules must shuttle reducing equivalents from the cytosol inward to reduce ascorbic acid oxidized during norepinephrine biosynthesis by intragranular dopamine-beta-hydroxylase. A transmembrane electron shuttle between the external (cytosolic) and intragranular ascorbate pools was demonstrated in vitro in intact bovine chromaffin granules undergoing tyramine- or dopamine-stimulated dopamine-beta-hydroxylase turnover. Incubation of intact chromaffin granules with tyramine results in a time-dependent decrease in reduced intragranular ascorbate and production of octopamine. The rate of ascorbate oxidation is a function of the extragranular concentrations of tyramine over the range 50 microM to 2 mM and is 95% inhibited by addition of the dopamine-beta-hydroxylase inhibitor disulfiram. The stoichiometry of octopamine synthesized/ascorbate oxidized closely approximates unity. The presence of extragranular dopamine also induces oxidation of intragranular ascorbate which is inhibited by blocking dopamine transport with reserpine. On the other hand, incubation with octopamine, which is also transported by the granules, causes no net decrease in reduced intragranular ascorbate. The presence of 400 microM extragranular ascorbate abolishes the observed tyramine-induced intragranular ascorbate oxidation. The addition of ascorbate extragranularly 30 min after addition of tyramine reverses the oxidation of intragranular ascorbate. The measurement of [14C]ascorbate distribution ratios in granule pellets and supernatants indicates that there is no transmembrane transport of ascorbate. Extravesicular NADH had no significant effect on matrix ascorbate levels during beta-hydroxylation. These data provide new in vitro evidence that chromaffin granules shuttle reducing equivalents inwardly from an extra- to an intravesicular ascorbate pool and that cytosolic ascorbate is the source of the intragranular reducing equivalents required during norepinephrine biosynthesis.     

Role of Mg-ATP in Norepinephrine Biosynthesis in Intact Chromaffin Granules

Abstract: Dopamine β-mdriooxygenase converts dopamine to norepinephrine in intact chromaffin granules using intragranular ascorbic acid as a cosubstrate. Mg-ATP with external ascorbic acid is required for maximal norepinephrine biosynthesis. Mechanisms to explain these requirements were investigated specifically using intact granules. The effect of Mg-ATP was independent of membrane potential (ΔΨ) because norepinephrine biosynthesis was unchanged whether ΔΨ was positive or collapsed. Furthermore, the effect of Mg-ATP was independent of absolute intragranular and extragranular pH as well as the pH difference across the chromaffin granule membrane (ΔpH). Nevertheless, norepinephrine biosynthesis was inhibited by N -ethylmaleimide, 4-chloro-7-nitrobenzofurazane, and N , N -dicyclohexylcarbodiimide, specific inhibitors of the secretory vesicle ATPase that may directly affect proton pumping. Biosynthesis occurred normally with other ATPase inhibitors that do not inhibit the ATPase in secretory vesicles. The data indicate that the effect of Mg-ATP with ascorbic acid is mediated by the granule membrane ATPase but independent of maintaining ΔΨ and ApH. An explanation of these findings is that Mg-ATP, via the granule ATPase, may change the rate at which protons or dopamine are made available to dopamine β-monooxygenase.     

Ascorbic acid regulation of norepinephrine biosynthesis in isolated chromaffin granules from bovine adrenal medulla

The effect of ascorbic acid on the conversion of dopamine to norepinephrine was investigated in isolated chromaffin granules from bovine adrenal medulla. Ascorbic acid was shown to double the rate of [3H]norepinephrine formation from [3H]dopamine, despite no demonstrable accumulation of ascorbic acid into chromaffin granules. The enhancement of norepinephrine biosynthesis by ascorbic acid was dependent on the external concentrations of dopamine and ascorbate. The apparent Km of the dopamine beta-hydroxylation system for external dopamine was approximately 20 microM in the presence or absence of ascorbic acid. However, the apparent maximum velocity of norepinephrine formation was nearly doubled in the presence of ascorbic acid. By contrast, the apparent Km and Vmax of dopamine uptake into chromaffin granules were not affected by ascorbic acid. Norepinephrine formation was increased by ascorbic acid when the concentration of ascorbate was 200 microM or higher; a concentration of 2 mM appeared to induce the maximal effect under the experimental conditions used here. The effect of ascorbic acid on conversion of dopamine to norepinephrine required Mg-ATP-dependent dopamine uptake into chromaffin granules. In contrast to ascorbic acid, other reducing agents such as NADH, glutathione, and homocysteine were unable to enhance norepinephrine biosynthesis. These data suggest that ascorbic acid provides reducing equivalents for hydroxylation of dopamine despite the lack of ascorbate accumulation into chromaffin granules. These findings imply the functional existence of an electron carrier system in the chromaffin granule which transfers electrons from external ascorbic acid for subsequent intragranular norepinephrine biosynthesis.     

Ascorbic acid and Mg-ATP co-regulate dopamine beta-monooxygenase activity in intact chromaffin granules

Ascorbic acid and Mg-ATP were found to regulate norepinephrine biosynthesis in intact secretory vesicles synergistically and specifically, using the model system of isolated bovine chromaffin granules. Dopamine uptake into chromaffin granules was shown to be unrelated to the presence of Mg-ATP and ascorbic acid at external dopamine concentrations of 7.5 and 10 mM. Under these conditions of dopamine uptake, norepinephrine biosynthesis was enhanced 5-6-fold by Mg-ATP and ascorbic acid compared to control experiments with dopamine only. Furthermore, norepinephrine formation was enhanced approximately 3-fold by ascorbic acid and Mg-ATP together compared to norepinephrine formation in granules incubated with either substance alone. The action of Mg-ATP and ascorbic acid together was synergistic and independent of dopamine content of chromaffin granules as well as of dopamine uptake. The apparent Km of norepinephrine formation for external ascorbic acid was 376 microM and for external Mg-ATP was 132 microM, consistent with the larger amounts of cytosolic ascorbic acid and ATP that are available to chromaffin granules. Other physiologic reducing agents were not able to increase norepinephrine biosynthesis in the presence or absence of Mg-ATP. In addition, maximum enhancement of norepinephrine biosynthesis occurred only with the nucleotide ATP and the cation magnesium. The mechanism of the effect of ascorbic acid and Mg-ATP on norepinephrine biosynthesis was investigated and appeared to be independent of a positive membrane potential. The effect was also not mediated by direct action of ADP, ATP, or magnesium on the activity of soluble or particulate dopamine beta-monooxygenase. These data indicate that Mg-ATP and ascorbic acid specifically and synergistically co-regulate dopamine beta-monooxygenase activity in intact chromaffin granules, independent of substrate uptake. Although the mechanism is not known, the data are consistent with the possibility that the chromaffin granule ATPase mediates these effects.     

Enhancement of norepinephrine biosynthesis by ascorbic acid in cultured bovine chromaffin cells

Ascorbic acid donates electrons to dopamine beta-monooxygenase during the hydroxylation of dopamine to norepinephrine in vitro. However, the possible role of ascorbic acid in norepinephrine biosynthesis in vivo has not been defined. We therefore investigated the effect of newly accumulated ascorbic acid on catecholamine biosynthesis in cultured bovine adrenal chromaffin cells. Cells supplemented for 3 h with ascorbic acid accumulated 9-fold more ascorbic acid than found in control cells. Under these conditions, the cells loaded with ascorbate were found to double the rate of norepinephrine biosynthesis from [14C]tyrosine compared to control. By contrast, the amounts present of [14C] 3,4-dihydroxyphenylalanine and [14C]dopamine synthesized from [14C]tyrosine were unaffected by the preloading of ascorbic acid. Ascorbate preloaded cells incubated with [3H]dopamine also showed a similar increase in the rate of norepinephrine formation, without any change in dopamine transport into the cells. Thus, these data were consistent with ascorbate action at the dopamine beta-monooxygenase step. In order to determine if ascorbate could interact directly with dopamine beta-monooxygenase localized within chromaffin granules, we studied whether isolated chromaffin granules could accumulate ascorbic acid. Ascorbic acid was not transported into chromaffin granules by an uptake or exchange process, despite coincident [3H]dopamine uptake which was Mg-ATP dependent. These data indicate that ascorbic acid does augment norepinephrine biosynthesis in intact chromaffin cells, but by a mechanism that might enhance the rate of dopamine hydroxylation indirectly.     

Electron transfer in chromaffin-vesicle ghosts containing peroxidase.

In chromaffin vesicles, the enzyme dopamine beta-monooxygenase converts dopamine to norepinephrine. It is believed that reducing equivalents for this reaction are supplied by intravesicular ascorbic acid and that the ascorbate is regenerated by importing electrons from the cytosol with cytochrome b-561 functioning as the transmembrane electron carrier. If this is true, then the ascorbate-regenerating system should be capable of providing reducing equivalents to any ascorbate-requiring enzyme, not just dopamine beta-monooxygenase. This may be tested using chromaffin-vesicle ghosts in which an exogenous enzyme, horseradish peroxidase, has been trapped. If ascorbate and peroxidase are trapped together within chromaffin-vesicle ghosts, cytochrome b-561 in the vesicle membrane is found in the reduced form. Subsequent addition of H2O2 causes the cytochrome to become partially oxidized. H2O2 does not cause this oxidation if either peroxidase or ascorbate are absent. This argues that the cytochrome is oxidized by semidehydroascorbate, the oxidation product of ascorbate, rather than by H2O2 or peroxidase directly. The semidehydroascorbate must be internal because the ascorbate from which it is formed is sequestered and inaccessible to external ascorbate oxidase. This shows that cytochrome b-561 can transfer electrons to semidehydroascorbate within the vesicles and that the semidehydroascorbate may be generated by any enzyme, not just dopamine beta-monooxygenase.     

Ascorbic acid specifically enhances dopamine beta-monooxygenase activity in resting and stimulated chromaffin cells

Ascorbic acid enhancement of norepinephrine formation from tyrosine in cultured bovine chromaffin cells was characterized in detail as a model system for determining ascorbate requirements. In resting cells, ascorbic acid increased dopamine beta-monooxygenase activity without changing tyrosine 3-monooxygenase activity. [14C]Norepinephrine specific activity was increased by ascorbic acid, while [14C]dopamine specific activity was unchanged. Dopamine content, dopamine biosynthesis, tyrosine content, and tyrosine uptake were also unaffected by ascorbic acid. Furthermore, increased norepinephrine formation could not be attributed to changes in norepinephrine catabolism. Enhancement of dopamine beta-monooxygenase activity was specific for ascorbic acid, since other reducing agents with higher redox potentials were unable to increase norepinephrine formation. The specific effect of ascorbic acid on enhancement of norepinephrine formation was also observed in chromaffin cells stimulated to secrete with carbachol, acetylcholine, veratridine, and potassium chloride. In stimulated cells with and without ascorbate, there were no differences in dopamine content, tyrosine uptake, dopamine specific activity, and norepinephrine catabolism. These data indicate that, under a wide variety of conditions, only one catecholamine biosynthetic enzyme activity, dopamine beta-monooxygenase, is specifically stimulated by ascorbic acid alone in cultured chromaffin cells. This model system exemplifies a new approach for determining ascorbic acid requirements in cells and animals.     

Electron transfer across posterior pituitary neurosecretory vesicle membranes

Secretory vesicles from the neurohypophysis have a transmembrane electron carrier very similar to that found in adrenal medullary chromaffin granules. Two different tests show that ascorbic acid contained in the vesicles will reduce an external electron acceptor. First, reduction of cytochrome c or ferricyanide in the medium by a neurosecretory vesicle suspension can be followed spectrophotometrically. Second, the membrane potential (inside positive) generated by electron transfer can be monitored using the membrane potential-sensitive optical probe Oxonol VI. As in chromaffin granules, this electron transfer is probably mediated by cytochrome b561. It may function to regenerate internal ascorbic acid and to provide reducing equivalents needed by the intravesicular amidating enzyme.     

Hyperosmotic relaxation lysis of chromaffin granules is caused by interactions between the granular membrane and intragranular vesicles

Bovine chromaffin granules undergo irreversible structural changes during osmotic shrinkage in hypertonic sucrose and salt solutions, such that, on reexposure to isoosmotic conditions they do not regain their original morphology, but undergo lysis ('hyperosmotic relaxation lysis'). Irreversible alterations of granules were induced by hypertonic incubations lasting for as little as 1 min. Fluorescence and EPR membrane labelling experiments showed that hypertonicity did not induce membrane loss for instance by inwardly or outwardly directed pinching off of membrane material. The mean sizes of chromaffin granules as a function of increasing and subsequently decreasing osmotic pressure were measured by photon correlation spectroscopy; there was no significant difference in sizes of hyperosmotically pretreated granules as compared with controls. Freeze-fracture electron micrographs showed the formation of 'twins' and 'triplets' under hypertonic conditions. They also revealed intragranular vesicles of 50-200 nm in diameter in both hypertonically and isotonically suspended granules. 'Twin' and 'triplet' granules were formed by the attachment of intragranular vesicles to the granule membranes. We suggest that hyperosmotic relaxation lysis is caused by the fact that this adhesion partly prevents the granule membrane from reexpanding, thus, leading to its rupture.     

Continuous spectrophotometric assays for dopamine beta-monooxygenase based on two novel electron donors: N,N-dimethyl-1,4-phenylenediamine and 2-aminoascorbic acid.

Based on the novel chromophoric electron donors, N,N-dimethyl-1,4-phenylenediamine (DMPD) and 2-amino-2-deoxy-L-ascorbic acid (2-aminoascorbic acid), two sensitive, convenient, and continuous spectrophotometric assays for dopamine beta-monooxygenase (EC 1.14.17.1) are described. Both, DMPD and 2-aminoascorbic acid are kinetically and stoichiometrically well-behaved electron donors for dopamine beta-monooxygenase with kinetic parameters comparable to the most efficient physiological electron donor, ascorbic acid. During dopamine beta-monooxygenase turnover, DMPD is converted to its chromophoric cation radical which is stable under the standard assay conditions. The rate of the enzyme-dependent formation of DMPD cation radical under standard assay conditions could easily be followed at 515 nm with high accuracy and reproducibility. Similarly, dopamine beta-monooxygenase-mediated oxidation of 2-aminoascorbic acid results in the formation of the known, stable chromophoric product, 2,2'-nitrilodi-2(2')-deoxy-L-ascorbic acid (red pigment), which has a very strong absorption maximum at 385 nm. Both the above assays are superior to the existing assays in their convenience, reproducibility, and sensitivity for routine kinetic analysis of dopamine beta-monooxygenase and may be adopted as a simple color test for the enzyme. We propose that the above assays could also be adopted to design continuous and sensitive spectrophotometric assays for ascorbate oxidase, peptidyl alpha-amidating monooxygenase, and the chromaffin granule electron transport protein, cytochrome b561, due to their remarkable similarity to dopamine beta-monooxygenase in the chemistry of catalysis with regard to the electron donor.     

Catecholamine transport and energy-linked function of chromaffin granules isolated from a human pheochromocytoma

The structure and function of chromaffin granulles of human phoechromocytoma was extensively investigated in a highly purified granule fraction obtained from a single specimen of human pheochromocytoma tissue. Pheochromocytoma chromaffin granules were analyzed for catecholamine, ATP, enkephalin, phospholipid, cytochrome and ion content. Using a variety of techniques it was found that the membrane of these granules is highly impermeable to Na⁺, K⁺, and H⁺, and that the intragranular pH was maintained at 5.1 irrespective of suspending media. The presence of MgATP induces a transmembrane potential (ΔΨ) across the membrane of these granules which is positive inside and which corresponds to 90 mV. Both ΔpH and ΔΨ are coupled to biogenic amine accumulation into the granules in a process which is reserpine sensitive. These properties are compared with those of chromaffin granules isolated from normal human tissue or from other animal species and are discussed in terms of possible explanation at a biochemical or subcellular level of the clinical manifestation of the pheochromocytoma.     

Stimulatory Effect of Ascorbic Acid on Norepinephrine Biosynthesis in Digitonin-Permeabilized Adrenal Medullary Chromaffin Cells

The regulatory role of ascorbic acid in norepinephrine biosynthesis was studied using digitonin-permeabilized chromaffin cells. When permeabilized chromaffin cells were incubated with [3H]3,4-dihydroxyphenylethylamine ([3H]dopamine) in calcium-free medium, the amounts of radioactive dopamine and norepinephrine measured in the cell fraction were increased as a function of incubation time and dopamine concentration. Both the accumulation of dopamine and the formation of norepinephrine were shown to require the presence of Mg-ATP in the medium. These results indicate that the permeabilization of chromaffin cells by digitonin treatment does not disrupt the functions of chromaffin granules, including dopamine uptake, norepinephrine formation, and storage of these amines. Using this permeabilized cell system, the effect of ascorbic acid on the rates of dopamine uptake and hydroxylation was investigated. The formation of norepinephrine was stimulated by ascorbic acid at concentrations of 0.5-2 mM in the presence of Mg-ATP. By contrast, dopamine uptake was not affected by the presence or absence of ascorbic acid in the medium. These findings provide evidence that ascorbic acid may stimulate the conversion of dopamine to norepinephrine by increasing dopamine beta monooxygenase activity rather than by increasing the substrate supply of dopamine. These observations also suggest that the rate of norepinephrine biosynthesis in adrenal medullary cells may be regulated by the concentration of ascorbic acid within the cell cytoplasm.     

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.     

Intragranular vesicles: new organelles in the secretory granules of adrenal chromaffin cells

Summary Chromaffin granules from bovine adrenal medullary chromaffin cells have been found to contain small vesicular structures bounded by unit membranes. Detection of these intragranular vesicles within intact cells requires the use of quick-freezing methods. The intragranular vesicles are labile to fixation by aldehydes which explains why they have not been described in intact cells until now. They are found in approximately 60% of the dense-core chromaffin granules in cells and 85% of isolated granules. They are usually clustered in groups of one to as many as five between the core and the inner surface of the granule membrane. The intragranular vesicles are independent vesicles in that they do not appear as simple invaginations of the granule membrane in either serial thin-section or freeze-etch views. Furthermore, they are released from the cell along with granule contents during nicotine-induced secretion of catecholamines. The structural heterogeneity provided by the intragranular vesicles may be related to the functional heterogeneity of granule contents observed in many recent biochemical studies.     

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.     

On the interaction between chromaffin granule membranes and intragranular vesicles--theory and analysis of freeze-fracture micrographs

We present a model for the calculation of intragranular vesicle adhesion energy in a two-vesicle system consisting of an external secretory vesicle (chromaffin granule) and an intragranular vesicle (IGV) that adheres from the inside to the granule membrane. The geometrical parameters characterizing the granule-IGV systems were derived from freeze-fracture electron micrographs. Adhesion is brought about by incubation of the granules in hyperosmolar sucrose solutions. It is accompanied by a deformation of the granule because the intragranular vesicle bulges it outwards, and by segregation of intramembraneous particles from the adherent part of the granule membrane. Adhesion prevents the deformed granules from osmotic reexpansion and, therefore, causes hyperosmotic relaxation lysis. We estimated specific adhesion energy at -3 erg/cm2, a value which is 10 - 1000 times larger than the energy of van der Waals interaction between membranes. This large interaction energy probably results from changes of the granule core induced by dehydration. A minimization of the interface between the granule core and adjacent membranes could exclude intragranular vesicles from the core and squeeze them towards the granule membrane. This might induce a new kind of interaction between both membranes, which is irreversible and causes lysis upon osmotic relaxation.     

A monoclonal anticarbohydrate antibody detecting superfast myosin in the masseter muscle

Adrenal medullary chromaffin cells secrete catecholamines through exocytosis of their intracellular chromaffin granules. Osmotic granule swelling has been implicated to play a role in the generation of membrane stress associated with the fusion of the granule membrane. However, controversy exists as to whether swelling occurs before or after the actual fusion event. Using morphometric methods we have determined the granule diameter distributions in rapidly frozen, freeze-substituted chromaffin cells. Our measurements show that intracellular chromaffin granules increase in size from an average of 234 nm to 274 nm or 277 nm in cells stimulated to secrete with nicotine or high external K⁺, respectively. Granule swelling occurs before the formation of membrane contact. Ammonium chloride, an agent which inhibits stimulated catecholamine secretion by approximately 50% by altering the intragranular pH, also inhibits granule swelling. In addition, ammonium chloridetreated secreting cells show more granule-plasma membrane contacts than untreated secreting cells. Sodium propionate induces granule swelling in the absence of secretagogue and has been shown to enhance nicotine- and high K⁺- induced catecholamine release. These results indicate that in adrenal chromaffin cells granule swelling is an essential step in exocytosis before fusion pore formation, and is related to the pH of the granule environment.     

Rate of transmembrane electron transfer in chromaffin-vesicle ghosts

The chromaffin vesicle of the adrenal medulla contains a transmembrane electron carrier that may provide reducing equivalents for dopamine beta-hydroxylase in vivo. This electron-transfer system can be assayed by trapping ascorbic acid inside resealed membrane vesicles (ghosts), adding an external electron acceptor such as ferricytochrome c or ferricyanide, and following the reduction of these acceptors spectrophotometrically. Cytochrome c reduction is more rapid at high pH and is proportional to the amount of chromaffin-vesicle ghosts, at least at low ghost concentrations. At pH 7.0, ghosts loaded with 100 mM ascorbic acid reduce 60 microM cytochrome c at a rate of 0.035 +/- 0.010 mu equiv min-1 (mg of protein)-1 and 200 microM ferricyanide at a rate of 2.3 +/- 0.3 mu equiv min-1 (mg of protein)-1. The rate of cytochrome c reduction is accelerated to 0.105 +/- 0.021 mu equiv min-1 (mg of protein)-1 when cytochrome c is pretreated with equimolar ferrocyanide. Pretreatment of cytochrome c with ferricyanide also causes a rapid rate of reduction, but only after an initial delay. The ferrocyanide-stimulated rate of cytochrome c reduction is further accelerated by the protonophore carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP), probably because FCCP dissipates the membrane potential generated by electron transfer. These rates of electron transfer are sufficient to account for electron transfer to dopamine beta-hydroxylase in vivo and are consistent with the mediation of electron transfer by cytochrome b-561.