Mechanism of secretory granule exocytosis: can granule enlargement precede pore formation?

Secretory granules have been observed to swell during the process of exocytosis. Swelling is an indication of osmotic stress. The probable role of osmotic pressure in facilitating membrane fusion makes it necessary to determine whether granule membrane 'swelling' can occur prior to its fusion with the plasma membrane (pore formation) in the process of exocytosis. By subjecting adjacent thin and semi-thin sections of an activated granule to ultrastructural examination for membrane enlargement, and to metachromatic staining for verification of pore formation it is concluded that the perigranular membrane can indeed enlarge prior to pore formation. However, the degree of membrane enlargement can far exceed the limit of 2-3% stretching allowed under normal osmotic stress for a membrane bilayer. Such an extensive membrane enlargement, which takes place in the mechanism of exocytosis, cannot be achieved without being accompanied by the insertion of additional membrane.     

Effects of hyposmotic stress on exocytosis in isolated turbot, Scophthalmus maximus, hepatocytes

The effect of hyposmotic shock on exocytosis was examined in isolated hepatocytes of turbot, a marine flatfish, using the molecular probe FM1-43. Sudden exposure to a reduced osmolality caused an increase in cell exocytic activity related to the osmotic gradient between intra- and extracellular fluids. Cytoskeletal microtubules could contribute to this hyposmotic-induced exocytosis since colchicine inhibited the process. Protein kinase C, phosphatidylinositol-3 kinase, phospholipases A2, C and D could constitute key enzymes in the mechanism since their inhibition by specific agents altered the hyposmotic-induced exocytic activity. Moreover, arachidonic acid and derivates from the 5-lipoxygenase pathway as well as calcium could participate in the process. As regulatory volume decrease (RVD) exhibited by turbot hepatocytes following hyposmotic stimulation involves similar features, a potential role of exocytosis in volume regulation is suggested. In particular, exocytosis could serve RVD by contributing to ATP release since this latter process similarly appeared to be phospholipase D-dependent and related to the osmotic gradient. This study provides the first evidence of a volume-sensitive exocytosis that could aim at volume constancy in a marine teleost fish cell type.     

Effects of changes in osmolality on the stability and function of cultured chromaffin cells and the possible role of osmotic forces in exocytosis

Recent evidence indicates that osmotic forces may play a role in exocytosis. To examine this possibility and to investigate the osmotic properties of storage granules within cells, we investigated the effects of changes of osmolality on stability and function of cultured bovine chromaffin cells. Cell volume measurements indicated that the cells behaved as osmometers and that the intracellular osmolality rapidly equilibrated with the osmolality of the extracellular medium. Hyperosmotic solutions strongly inhibited nicotinic agonist-stimulated secretion but did not alter nicotinic agonist-stimulated Ca(2+) uptake. Hyperosmotic solutions also strongly inhibited elevated potassium- stimulated secretion but only weakly inhibited elevated K(+)-stimulated Ca(2+) uptake. Thus, hyperosmotic solutions inhibited secretion at a step after calcium entry. Cells exposed to 165 mOs(1) solutions did not lyse and retained their capacity to store and secrete catecholamine upon stimulation. Significant intracellular lysis of chromaffin granules occurred within cells exposed to lower osmolalities. In contrast, 75 percent of the catecholamine was released from granules from cultured cells or from fresh adrenal medulla incubated in vitro at 210 mOs. The data provide evidence for a role for osmotic forces in exocytosis and suggest that if osmotic stress of the granule occurs during exocytosis, then water influx into chromaffin granules increases granule volume by at least 70 percent. The results also indicate that the osmotic properties of the granules are altered upon homogenization and subcellular fractionation of the cells.     

Endocytosis and exocytosis protect cells against severe membrane tension variations

The ability of cells to regulate their shape and volume is critical for many cell functions. How endocytosis and exocytosis, as important ways of membrane trafficking, affect cellular volume regulation is still unclear. Here, we develop a theoretical framework to study the dynamics of cell volume, endocytosis, and exocytosis in response to osmotic shocks and mechanical loadings. This model can not only explain observed dynamics of endocytosis and exocytosis during osmotic shocks but also predict the dynamics of endocytosis and exocytosis during cell compressions. We find that a hypotonic shock stimulates exocytosis, while a hypertonic shock stimulates endocytosis; and exocytosis in turn allows cells to have a dramatic change in cell volume but a small change in membrane tension during hyposmotic swelling, protecting cells from rupture under high tension. In addition, we find that cell compressions with various loading speeds induce three distinct dynamic modes of endocytosis and exocytosis. Finally, we show that increasing endocytosis and exocytosis rates reduce the changes in cell volume and membrane tension under fast cell compression, whereas they enhance the changes in cell volume and membrane tension under slow cell compression. Together, our findings reveal critical roles of endocytosis and exocytosis in regulating cell volume and membrane tension.     

Hypertonic inhibition of exocytosis in neutrophils: central role for osmotic actin skeleton remodeling

Hypertonicity suppressesneutrophil functions by unknown mechanisms. We investigated whetherosmotically induced cytoskeletal changes might be related to thehypertonic inhibition of exocytosis. Hyperosmolarity abrogated themobilization of all four granule types induced by diverse stimuli,suggesting that it blocks the process of exocytosis itself rather thanindividual signaling pathways. Concomitantly, osmotic stress provoked atwofold increase in F-actin, induced the formation of a submembranousF-actin ring, and abolished depolymerization that normally followsagonist-induced actin assembly. Several observations suggest a causalrelationship between actin polymerization and inhibition of exocytosis:1) prestimulus actin levels were inversely proportional tothe stimulus-induced degranulation, 2) latrunculin B (LB)prevented the osmotic actin response and restored exocytosis, and3) actin polymerization induced by jasplakinolide inhibitedexocytosis under isotonic conditions. The shrinkage-induced tyrosinephosphorylation and the activation of theNa⁺/H⁺ exchanger were not affected by LB.Inhibition of osmosensitive kinases failed to prevent the F-actinchange, suggesting that the osmotic tyrosine phosphorylation and actinpolymerization are independent phenomena. Thus cytoskeletal remodelingappears to be a key component in the neutrophil-suppressive,anti-inflammatory effects of hypertonicity.

     

Exocytosis of sea urchin egg cortical vesicles in vitro is retarded by hyperosmotic sucrose: kinetics of fusion monitored by quantitative light-scattering microscopy

We have used the isolated planar cortex of sea urchin eggs to examine the role of osmotic forces in exocytosis by morphological and physiological methods. Electron micrographs of rotary-shadowed replicas show an en face view of exocytosis and demonstrate fusion of cortical vesicles to the underlying oolemma upon addition of calcium. Freeze- fracture replicas of rapidly frozen cortices reveal specialized attachment sites between cortical vesicles and the oolemma, and between the cortical vesicles themselves. We describe a novel light scattering assay for the kinetics of fusion which allows rapid changes of solutions and monitors exocytosis in real time. The rate and extent of fusion are found to be calcium dependent. The removal of calcium halts exocytosis. The validation of exocytosis in this system and development of tools for kinetic analysis allowed us to test predictions of the osmotic hypothesis of exocytosis: hyperosmotic media should inhibit exocytosis; calcium should cause vesicular swelling. Cortical vesicles were found to be permeant to sucrose, glucose, and urea. In media made hyperosmotic with 1.7 M sucrose, cortical vesicles were seen to shrink. Addition of calcium in hyperosmotic media led to a 10-fold decrease in the rate of exocytosis compared with the isotonic rate. The rate, while triggered by calcium, was no longer calcium-dependent. This slowing of exocytosis allowed us to photograph the swelling of cortical vesicles caused by calcium. Removal of calcium had no effect on subsequent exocytosis. Return of cortices to isotonic medium without calcium led to immediate exocytosis. These results are consistent with the idea that swelling of cortical vesicles is required for fusion of biological membranes.     

Role of calcium in triggering the release of transmitters at the neuromuscular junction

Calcium ions have a key role in triggering the release of packaged transmitter at the amphibian neuromuscular junction and of the chromaffin granules at the adrenal medulla. It is suggested that (i) proteins on the vesicle and plasma membranes are of particular importance in promoting membrane fusion and exocytosis (ii) they may be divalent cation-stimulated ATPases, which form the calcium-binding sites or have a specific calcium-binding protein in close molecular apposition (iii) these ATPases in synaptic vesicles and chromaffin granules also generate a protonmotive force which is associated with the uptake of transmitter (iv) the osmotic properties of the vesicle may be important during fission, but it is not suggested that chemiosmotic effects are involved in Ca2+-triggered fusion (v) the action of calcium is markedly co-operative (vi) the adrenal medullary cell and the n.m.j. may differ in the Ca2+-binding site; there is evidence for the involvement of calmodulin in granule-plasmalemma fusion in the chromaffin cells, but not at present (surprisingly) for a role of this Ca2+-binding protein at the n.m.j. (vii) exocytosis requires MgATP (viii) phosphorylation of the ATPase may well be involved; phosphorylation via cAMP does not seem to be involved in fusion in either system (ix) the ATPase may undergo configurational changes during exocytosis and is markedly sensitive to the physical state of its phospholipid environment and to the oxidation of its -SH groups.     

Calcium control of exocytosis and endocytosis in bovine adrenal medullary cells

Experimental analysis of the mechanisms of exocytosis and endocytosis has hitherto been hampered by the inaccessibility of the intracellular sites at which they are controlled. We have recently developed a technique that overcomes this problem. Cells are subjected to intense electric fields of brief duration; this renders the plasma membrane permeable without impairing its ability to participate in exocytosis and endocytosis. Working with 'leaky' bovine adrenal medullary cells, catecholamine release has a rather specific requirement for Mg-ATP, is activated by micromolar concentrations of ionized Ca and can be inhibited by Mg, detergents, trifluoperazine, high osmotic pressure and various anions. The mechanism of activation by Ca is discussed in some detail.     

A model for exocytosis based on the opening of calcium-activated potassium channels in vesicles

It is proposed that the role of calcium in calcium-induced exocytosis is to open Ca-activated K channels present in vesicle membranes. The opening of these channels coupled with anion transport across the vesicle membranes would result in an influx of K and anions, increasing the osmotic pressure of the vesicles. For those vesicles situated very close to the cell plasma membrane, this would lead to fusion with the membrane and exocytosis of the vesicle contents. This model can account for facilitation and other key properties of transmitter release. In addition, the model predicts that vesicles with a higher transmitter content, and hence higher initial osmotic pressure, would be preferentially discharged. The model also predicts that a faster response can be obtained for small vesicles than for large vesicles, providing a rationale as to why neurotransmitters, which must be released quickly, are packaged in small vesicles.     

Role of calmodulin in antidiuretic hormone mediated water transport

Several classes of tricyclic antidepressants inhibit the action of antidiuretic hormone (ADH) and cyclic adenine monophosphate (cAMP) on osmotic water flow across toad urinary bladder without any effect on sodium transport. This finding suggests that calmodulin is involved in the hydroosmotic action of ADH (and of serosal hypertonicity), possibly in inducing exocytosis at the luminal border of vesicles rich in water channels.     

Regulation by Ca2+ of membrane elasticity of bovine chromaffin granules

In a range of [Ca2+] similar to cytosolic transient, a drastic reduction from about 20 dyn/cm to almost zero was observed in the membrane elastic modulus of bovine chromaffin granules, isolated in a solution containing 0.3 M sucrose and 5 mM Hepes at pH 7.0, and measured by combination of osmotic swelling and dynamic light-scattering (DLS) methods. This result suggests that the granule membrane becomes extremely flexible as a prelude to exocytosis.     

Effects of osmotic stress on mast cell vesicles of the beige mouse

The large size of the vesicles of beige mouse peritoneal mast cells (4 microns in diameter) facilitated the direct observation of the individual osmotic behavior of vesicles. The vesicle diameter increased as much as 73% when intact cells were perfused with a 10 mM pH buffer solution; the swelling of the vesicle membranes exceeded that of the insoluble vesicle gel matrix, which resulted in the formation of a clear space between the optically dense gel matrix and the vesicle membrane. Hypertonic solutions shrank intact vesicles of lysed cells in a nonideal manner, suggesting a limit to the compressibility of the gel matrix. The nonideality at high osmotic strengths can be adequately explained as the consequence of an excluded volume and/or a three-dimensional gel-matrix spring. The observed osmotic activity of the vesicles implies that the great majority of the histamine known to be present is reversibly bound to the gel matrix. This binding allows vesicles to store a large quantity of transmitter without doing osmotic work. The large size of the vesicles also facilitated the measurement of the kinetics of release as a collection of individual fusion events. Capacitance measurements in beige mast cells revealed little difference in the kinetics of release in hypotonic, isotonic, and hypertonic solutions, thus eliminating certain classes of models based on the osmotic theory of exocytosis for mast cells.     

Osmotic regulation of prolactin secretion. Possible role of chloride

The role of osmotic pressure in the exocytosis of prolactin from rat pituitary tumor (GH) cells in culture was investigated. Reducing the osmotic strength of the medium from 300 mosm to 150 mosm by removal of NaCl did not alter basal secretion of prolactin but inhibited secretion stimulated by thyrotropin-releasing hormone (TRH) and forskolin. Both basal and stimulated secretion of prolactin were inhibited by increasing the osmotic strength of the medium with NaCl (IC50 at approximately 500 mosm). The stimulated release of hormone from GH-cells was independent of sodium and unaffected by replacement of sodium ion with tetramethylammonium or choline, or by addition of 500 nM tetrodotoxin. Secretagogue-stimulated release was, however, dependent upon chloride. Exchange of medium chloride with benzoate or isethionate significantly inhibited the stimulated release of prolactin (IC50 at approximately 60 mM exchange) regardless of the secretagogue utilized (phorbol ester, forskolin, depolarization plus BAY K8644, or TRH). Exchange of medium chloride with either isethionate or benzoate reduced cell volume by 10% compared to 60% for sucrose and mannitol, suggesting that inhibition of secretion by isethionate exchange was not a result of increased intracellular osmotic pressure. Complete exchange of medium chloride with isethionate did not alter equilibrium [3H]methyl-TRH binding, resting internal [Ca2+], or the [Ca2+]i response to depolarization and TRH as measured with intracellularly trapped Fura 2. Chloride removal did not change resting internal pH and recovery from an acid load as measured by the intracellular pH-sensitive dye 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein. The stimulated secretion of prolactin was also inhibited by exchange of chloride with isethionate in normal pituitary cells in primary culture and the ability of normal cells to respond to the dopamine agonist bromocryptine was not affected by the exchange. These results suggest that exocytosis of prolactin from GH-cells and normal pituitary cells in culture is an osmotically driven process that is chloride-dependent. Stimulated release is more chloride-dependent than constitutive release. The inhibitory effect of isethionate substitution occurs after signal transduction and is distinct from the site of dopamine inhibition of prolactin release.     

Quantitative analysis of exocytosis and endocytosis in the hydroosmotic response of toad bladder

Summary This study concerns the timing and magnitude of exocytosis and endocytosis in the granular cells of toad bladder during the hydroosmotic response to antidiuretic hormone. Granule exocytosis at the luminal cell surface is extensive within 5 min of the administration of a physiological dose of hormone. Hydroosmosis becomes detectable during this time period. The amount of membrane added to the luminal surface by exocytosis during 60 min of exposure to hormone can be of the same order of magnitude as the extent of the luminal plasma membrane. Endocytosis, demonstrated by peroxidase uptake from the luminal surface, becomes extensive during the period 15–45 min after hormone administration. Thus, maximal endocytic activity occurs later than the period of most extensive exocytosis and seems to correlate with the onset of the decline in water movement. The amount of membrane retrieved from the luminal surface by endocytosis during 60 min of stimulation is at least three quarters of that added by exocytosis. The bulk membrane movement in ADH stimulated preparations does not require the presence of an osmotic gradient. Colchicine inhibits the hydroosmotic response, the exocytosis of granules, and endocytosis at the luminal surface. These results strengthen our view that the bulk circulation of membrane at the cell surface, via exocytosis and endocytosis, is closely related to the permeability changes occuring at the surface.     

Separation of the osmotically driven fusion event from vesicle-planar membrane attachment in a model system for exocytosis

We demonstrate that there are two experimentally distinguishable steps in the fusion of phospholipid vesicles with planar bilayer membranes. In the first step, the vesicles form a stable, tightly bound pre-fusion state with the planar membrane; divalent cations (Ca++) are required for the formation of this state if the vesicular and/or planar membrane contain negatively charged lipids. In the second step, the actual fusion of vesicular and planar membranes occurs. The driving force for this step is the osmotic swelling of vesicles attached (in the pre- fusion state) to the planar membrane. We suggest that osmotic swelling of vesicles may also be crucial for biological fusion and exocytosis.     

Osmotic control of bilayer fusion

We have used photography and capacitance measurement to monitor the steps in the interaction and eventual fusion of optically black lipid bilayers (BLMs), hydrostatically bulged to approximately hemispherical shape and pushed together mechanically. A necessary first step is drainage of aqueous solution from between the bilayers to allow close contact of the bilayers. The drainage can be controlled by varying the osmotic difference across the bilayers. If the differences are such as to remove water from between the bilayers, fusion occurs after a time that depends on the net osmotic difference and the area of contact. If there is an osmotic flow of water into the space between the bilayers, fusion never occurs. In the fusion process, a single central bilayer forms from the original apposed pair of bilayers. The central bilayer may later burst to allow mixing of the two volumes originally bounded by the separate bilayer; the topological equivalent of exocytosis.     

ATP keeps exocytosis sites in a primed state but is not required for membrane fusion: an analysis with Paramecium cells in vivo and in vitro

We have tried to specify a widespread hypothesis on the requirement of ATP for exocytosis (membrane fusion). With Paramecium tetraurelia cells, synchronously (approximately 1 s) exocytosing trichocysts, ATP pools have been measured in different strains, including wild type cells, "non-discharge" (nd), "trichless" (tl), and other mutations. The occurrence of a considerable and rapid ATP consumption also in nd and tl mutations as well as its time course (with a maximum 3-5 s after exocytosis) in exocytosis-competent strains does not match the actual extent of exocytosis performance. However, from in vivo as well as from in vitro experiments, we came to the conclusion that ATP might be required to keep the system in a primed state and its removal might facilitate membrane fusion. (For the study of exocytosis in vitro we have developed a new system, consisting of isolated cortices). In vivo as well as in vitro exocytosis is inhibited by increased levels of ATP or by a nonhydrolyzable ATP analogue. In vitro exocytosis is facilitated in ATP-free media. In vivo-microinjected ATP retards exocytosis in response to chemical triggers, whereas microinjected apyrase triggers exocytosis without exogenous trigger. Experiments with this system also largely exclude any overlaps with other processes that normally accompany exocytosis. Our data also explain why it was frequently assumed that ATP would be required for exocytosis. We conclude that membrane fusion during exocytosis does not require the presence of ATP; the occurrence of membrane fusion might involve the elimination of ATP from primed fusogenic sites; most of the ATP consumption measured in the course of exocytosis may be due to other effects, probably to recovery phenomena.     

Angiotensin II inhibits the accumulation of cyclic AMP produced by glucagon but not its metabolic effects

Studies in model systems, as well as observations in intact cells, suggest that osmotic swelling of secretory granules is an essential step in exocytosis. A model is proposed whereby the low pH recorded in most secretory organelles could provide the driving force for granule swelling. The model assumes that during stimulation an exchange of H+ for alkali cations is triggered across the granule membrane. The outgoing H+ are rapidly replaced by the internal buffering capacity with a concomitant osmotic gain. The exchange is independent of anions and could be triggered by cytoplasmic Ca2+. The H+ -pump is responsible for the delta pH but independent of the exchange mechanism.