Focal exocytosis by eosinophils--compound exocytosis and cumulative fusion.

We have investigated the granule fusion events during exocytosis in horse eosinophils by time-resolved patch-clamp capacitance measurements. Stimulation with intracellular GTP gamma S leads to a stepwise capacitance increase by 4.0 +/- 0.9 pF. At GTP gamma S concentrations < 20 microM the step size distribution is in agreement with the granule size distribution in resting cells. Above 80 microM the number of steps is reduced and very large steps occur. The total capacitance increase, however, is unaffected. These results show that at high GTP gamma S concentrations granule--granule fusion occurs inside the cell forming large compound granules, which then fuse with the plasma membrane (compound exocytosis). The electrical equivalent circuit of the cell during degranulation indicates the formation of a degranulation sac by cumulative fusion events. Fusion of the first granule with the plasma membrane induces fusion of further granules with this granule directing the release of all the granular material to the first fusion pore. The physiological function of eosinophils is the killing of parasites. Compound exocytosis and cumulative fusion enable the cells to focus the release of cytotoxic proteins to well defined target regions and prevent uncontrolled diffusion of this material, which would damage intact host cells.     

Differential regulation of exocytotic fusion and granule-granule fusion in eosinophils by Ca2+ and GTP analogs

Dynamics of degranulation was studied in horse eosinophils by patch clamp capacitance measurements. Degranulation was stimulated by intracellular application of calcium, and GTPgammaS or guanosine 5'-(beta,gamma-imido)triphosphate at different concentrations via the patch pipette. Degranulation was quantified by measuring the delay time between the beginning of intracellular perfusion and the first exocytotic event, determining the distribution of time intervals between fusion events and the capacitance step size distributions under the different conditions. The degranulation dynamics could be well reproduced using a computer model assuming three independent rate constants for granule-plasma membrane fusion, granule fusion with already exocytosed granules, and intracellular granule-granule fusion. The rate of granule-plasma membrane fusion is sensitive to both, the GTP analog and [Ca2+]i. The rate of granule-exocytosed granule fusion is sensitive to [Ca2+]i but insensitive to the GTP analogs, and the rate of granule-to-granule fusion is sensitive to the GTP analog but insensitive to [Ca2+]i. Granule fusions with the three different target compartments thus involve different regulatory mechanisms.     

Identification of SNAREs involved in regulated exocytosis in the pancreatic acinar cell.

The molecular basis of exocytotic membrane fusion in the pancreatic acinar cell was investigated using an in vitro assay that measures both zymogen granule-plasma membrane fusion and granule-granule fusion. These two fusion events were differentially sensitive to Ca(2+), suggesting that they are controlled by different Ca(2+)-sensing mechanisms. Botulinum neurotoxin C (BoNT/C) treatment of the plasma membranes caused cleavage of syntaxin 2, the apical isoform of this Q-SNARE, but did not affect syntaxin 4, the basolateral isoform. BoNT/C also cleaved syntaxin 3, the zymogen granule isoform. BoNT/C treatment of plasma membranes abolished granule-plasma membrane fusion, whereas toxin treatment of the granules reduced granule-plasma membrane fusion and abolished granule-granule fusion. Tetanus toxin cleaved granule-associated synaptobrevin 2 but caused only a small reduction in both granule-plasma membrane fusion and granule-granule fusion. Our results indicate that syntaxin 2 is the isoform that mediates fusion between zymogen granules and the apical plasma membrane of the acinar cell. Syntaxin 3 mediates granule-granule fusion, which might be involved in compound exocytosis. In contrast, the major R-SNARE on the zymogen granule remains to be identified.     

Visualization of exocytotic secretory processes of mast cells by fluorescence techniques

Secretory processes via exocytosis in rat peritoneal mast cells were visualized by two complementary fluorescence techniques; one staining pre-exocytotic granules with a basic probe and the other staining post-exocytotic granules with acidic probes. Granules within mast cells were selectively stained with acridine orange and emitted orange yellow fluorescence. Upon stimulation with compound 48/80, release of acridine orange from granules was observed both in population and single cell measurements. This release was seen in some localized area of mast cells. Opening of pores between plasma membranes and granule membranes was monitored using acidic fluorescence probes such as 6-carboxyfluorescein or lucifer yellow CH. Not only granules located at peripheral region, but also granules near the core region participated in exocytosis. The existence of junctions between these granules was suggested. TMA-DPH, a lipophilic membrane probe, which was localized at plasma membrane before stimulation, diffused into granule membranes after stimulation. This shows that after stimulation, some constituents of plasma and granule membranes were mixed. Even after extensive degranulation, mast cells extruded acidic probes, indicating the plasma membranes still play a role of barrier. Activation of lateral motion of granules preceding to exocytosis was not observed. It was concluded that the visualization of secretory processes by fluorescence and image processing techniques will be useful for the study of molecular mechanisms underlying exocytosis.     

The dynamics of exocytosis in human neutrophils

We have investigated the dynamics of exocytosis in single human neutrophils. The increase of membrane area associated with granule fusion was followed by time-resolved patch-clamp capacitance measurements. Intracellular application of 20 microM guanosine-5'-O(3- thiotriphosphate) (GTP gamma S) in the presence of 2.5 mM ATP stimulated exocytosis and led to an increase of membrane capacitance from 3.0 to integral of 8.4 pF corresponding to a 540 micron 2 increase of membrane area. This capacitance change is very close to the value expected from morphological data if all primary and secondary granules fuse with the plasma membrane. High resolution measurements revealed stepwise capacitance changes corresponding to the fusion of individual granules. GTP gamma S-stimulated exocytosis did not require pretreatment with cytochalasin B and the amplitude was independent of the intracellular-free calcium concentration between 10 nM and integral of 2.5 microM. In the absence of GTP gamma S elevation of intracellular- free calcium concentration to the micromolar range led to the fusion of only a limited number of granules. Degranulation stimulated with GTP gamma S started after a lag phase of 2-7 min and was usually complete within 5-20 min. The time course was affected by the intracellular ATP and calcium concentration. Exocytosis was markedly accelerated by pretreatment with cytochalasin B. Our results demonstrate that the final steps leading to primary and secondary granule fusion are controlled by a guanine nucleotide-binding protein and do not require an elevation of intracellular calcium. Calcium and other factors are, however, involved in the regulation having pronounced effects on the dynamics of exocytosis.     

Exocytosis in bovine chromaffin cells: studies with patch-clamp capacitance and FM1-43 fluorescence

In response to physiological stimuli, neuroendocrine cells secrete neurotransmitters through a Ca(2+)-dependent fusion of secretory granules with the plasma membrane. We studied insertion of granules in bovine chromaffin cells using capacitance as a measure of plasma membrane area and fluorescence of a membrane marker FM1-43 as a measure of exocytosis. Intracellular dialysis with [Ca(2+)] (1.5-100 microM) evoked massive exocytosis that was sufficient to double plasma membrane area but did not swell cells. In principle, in the absence of endocytosis, the addition of granule membrane would be anticipated to produce similar increases in the capacitance and FM1-43 fluorescence responses. However, when endocytosis was minimal, the changes in capacitance were markedly larger than the corresponding changes in FM1-43 fluorescence. Moreover, the apparent differences between capacitance and FM1-43 fluorescence changes increased with larger exocytic responses, as more granules fused with the plasma membrane. In experiments in which exocytosis was suppressed, increasing membrane tension by osmotically induced cell swelling increased FM1-43 fluorescence, suggesting that FM1-43 fluorescence is sensitive to changes in the membrane tension. Thus, increasing membrane area through exocytosis does not swell chromaffin cells but may decrease membrane tension.     

Imaging exocytosis of single insulin secretory granules with evanescent wave microscopy: distinct behavior of granule motion in biphasic insulin release.

To study insulin exocytosis by monitoring the single insulin secretory granule motion, evanescent wave microscopy was used to quantitatively analyze the final stage of insulin exocytosis with biphasic release. Green fluorescent protein-tagged insulin transfected in MIN6 beta cells was packed in insulin secretory granules, which appeared to preferentially dock to the plasma membrane. Upon fusion evoked by secretagogues, evanescent wave microscopy revealed that fluorescence of green fluorescent protein-tagged insulin brightened, spread (within 300 ms), and then vanished. Under KCl stimulation, which represents the 1st phase of release, the successive fusion events were seen mostly from previously docked granules for the first minute, followed by the recruitment of new granules to the plasmalemmal docking sites. Stimulation with glucose, in contrast, caused the fusion events from previously docked granules for the first 120 s, thereafter a continuous fusion (2nd phase of release) was observed over 10 min mostly from newly recruited granules that progressively accumulated on the plasma membrane. Thus, our data revealed the distinct behavior of the insulin granule motion during the 1st and 2nd phase of release.     

Visualization of regulated exocytosis with a granule-membrane probe using total internal reflection microscopy

Secretory granules labeled with Vamp-green fluorescent protein (GFP) showed distinct signatures upon exocytosis when viewed by total internal reflection fluorescence microscopy. In approximately 90% of fusion events, we observed a large increase in fluorescence intensity coupled with a transition from a small punctate appearance to a larger, spreading cloud with free diffusion of the Vamp-GFP into the plasma membrane. Quantitation suggests that these events reflect the progression of an initially fused and spherical granule flattening into the plane of the plasma membrane as the Vamp-GFP simultaneously diffuses through the fusion junction. Approximately 10% of the events showed a transition from puncta to ring-like structures coupled with little or no spreading. The ring-like images correspond quantitatively to granules fusing and retaining concavity (recess of approximately 200 nm). A majority of fusion events involved granules that were present in the evanescent field for at least 12 s. However, approximately 20% of the events involved granules that were present in the evanescent field for no more than 0.3 s, indicating that the interaction of the granule with the plasma membrane that leads to exocytosis can occur within that time. In addition, approximately 10% of the exocytotic sites were much more likely to occur within a granule diameter of a previous event than can be accounted for by chance, suggestive of sequential (piggy-back) exocytosis that has been observed in other cells. Overall granule behavior before and during fusion is strikingly similar to exocytosis previously described in the constitutive secretory pathway.     

Docking and fusion of insulin secretory granules in SUR1 knock out mouse beta-cells observed by total internal reflection fluorescence microscopy

To explore how the sulfonylurea receptor (SUR1) is involved in docking and fusion of insulin granules, dynamic motion of single insulin secretory granules near the plasma membrane was examined in SUR1 knock-out (Sur1KO) beta-cells by total internal reflection fluorescence microscopy. Sur1KO beta-cells exhibited a marked reduction in the number of fusion events from previously docked granules. However, the number of docked granules declined during stimulation as a consequence of the release of docked granules into the cytoplasm vs. fusion with the plasma membrane. Thus, the impaired docking and fusion results in decreased insulin exocytosis from Sur1KO beta-cells.     

Roles of microfilaments in exocytosis: a new hypothesis

We observed the dynamic changes in the localization of microfilaments during the exocytic secretion of rat parotid and submandibular gland acinar cells, and obtained results which led us to propose a new concept of microfilament function in exocytosis. With the electron microscopy, NBD-Phallacidin (NBD-PL) fluorescence technique and immunohistochemistry for myosin, microfilaments consisting of F-actin and myosin were localized mainly underneath the luminal plasma membrane. Microfilaments were not detectable around the secretory granules which were stored in the cytoplasm, but were clearly observed around them whose membranes were continuous with the luminal plasma membrane. When viewed with NBD-PL and myosin fluorescence, the area of fused granule membranes revealed bright fluorescence in association with the luminal border, so that the luminal membrane undergoing exocytosis appeared like a 'bunch of grapes'. When excess exocytosis was stimulated by isoproterenol (IPR), the number of individual 'grapes' increased dramatically, indicating that the secretory granules are surrounded by microfilaments after the fusion with the luminal membrane. Microfilaments thus continuously undercoat the luminal membrane during exocytosis although the exocytic process involves the dilation and subsequent reduction of the luminal membrane due to the addition and removal of secretory granule membranes. This reduction of the dilated luminal membrane following exocytosis was, however, inhibited when the microfilaments were disrupted by cytochalasin D. Following this treatment, the lumina was expanded extraordinarily and the secretory products remained in the enlarged lumina, showing that the release of secretory products is inhibited when the microfilament function is disturbed. These results indicate that 1) microfilaments are localized mainly underneath the luminal plasma membrane and act as an obstacle to exocytosis when cells are at the resting phase and 2) at the secretory phase microfilaments allow exocytosis by disorganizing their barrier system and then, by encircling the discharged secretory granule membranes, provide forces for the extrusion of secretory products through the action of the acto-myosin contractile system.     

Two modes of lytic granule fusion during degranulation by natural killer cells

Lytic granules in cytotoxic lymphocytes, which include T cells and natural killer (NK) cells, are secretory lysosomes that release their content upon fusion with the plasma membrane (PM), a process known as degranulation. Although vesicle exocytosis has been extensively studied in endocrine and neuronal cells, much less is known about the fusion of lytic granules in cytotoxic lymphocytes. Here, we used total internal reflection fluorescence microscopy to examine lytic granules labeled with fluorescently tagged Fas ligand (FasL) in the NK cell line NKL stimulated with phorbol ester and ionomycin and in primary NK cells activated by physiological receptor-ligand interactions. Two fusion modes were observed: complete fusion, characterized by loss of granule content and rapid diffusion of FasL at the PM; and incomplete fusion, characterized by transient fusion pore opening and retention of FasL at the fusion site. The pH-sensitive green fluorescence protein (pHluorin) fused to the lumenal domain of FasL was used to visualize fusion pore opening with a time resolution of 30?ms. Upon incomplete fusion, pHluorin emission lasted several seconds in the absence of noticeable diffusion. Thus, we conclude that lytic granules in NK cells undergo both complete and incomplete fusion with the PM, and propose that incomplete fusion may promote efficient recycling of lytic granule membrane after the release of cytotoxic effector molecules.     

Capacitance flickers and pseudoflickers of small granules, measured in the cell-attached configuration.

We have studied exocytosis of single small granules from human neutrophils by capacitance recordings in the cell-attached configuration. We found that 2.2% of the exocytotic events were flickers. The flickers always ended with a downward step. This indicates closing of the fusion pore. During flickering, the fusion pore conductance remained below 1 nS, and no net membrane transfer was detectable. After fusion pore expansion beyond 1 nS the pore expanded irreversibly, leading to rapid full incorporation of the granule/vesicle into the plasma membrane. Following exocytosis of single granules, a capacitance decrease directly related to the preceding increase was observed in 7% of the exocytotic events. This decrease followed immediately after irreversible pore expansion, and is presumably triggered by full incorporation of the vesicle into the patch membrane. The capacitance decrease could be interpreted as endocytosis triggered by exocytosis. However, the gradual decrease could also reflect a decrease in the "free" patch area following incorporation of an exocytosed vesicle. We conclude that non-stepwise capacitance changes must be interpreted with caution, since a number of factors go into determining cell or patch admittance.     

Compound versus multigranular exocytosis in peritoneal mast cells

We have used the whole-cell patch-pipette technique to measure the step increases in the cell membrane capacitance (equivalent to the membrane area) caused by the fusion of secretory granules in degranulating murine mast cells. We have observed that up to 30% of the total membrane expansion caused by degranulation results from large fusion events that cannot be explained by the fusion of single secretory granules. These large events are observed mainly in the initial phase of a degranulation. We have developed a simple mathematical model for a mast cell to test whether these large events are caused by a stimulus-induced, granule-to-granule fusion that occurs before their exocytosis (multigranular exocytosis). Our results suggest that the large fusion events are caused by the exocytosis of granule aggregates that existed before stimulation and that are located at the cell's periphery. We propose a novel mechanism by which granule aggregates can be formed at the periphery of the cell. This mechanism relies on the ability of a transiently fused granule ("flicker") to fuse with more internally located granules in a sequential manner. This pattern may result in the formation of larger peripheral granules that later on can fuse with the membrane. The formation of peripheral granule aggregates may potentiate a subsequent secretory response.     

Myosin 5a controls insulin granule recruitment during late-phase secretion

We have examined the importance of the actin-based molecular motor myosin 5a for insulin granule transport and insulin secretion. Expression of myosin 5a was downregulated in clonal INS-1E cells using RNAinterference. Stimulated hormone secretion was reduced by 46% and single-cell exocytosis, measured by capacitance recordings, was inhibited by 42% after silencing. Silencing of Slac-2c/MYRIP, which links insulin granules to myosin 5a, resulted in similar inhibition of single-cell exocytosis. Antibody inhibition of the myosin 5a-Slac-2c/MYRIP interaction significantly reduced the recruitment of insulin granules for release. The pool of releasable granules independent of myosin 5a activity was estimated to approximately 550 granules. Total internal reflection microscopy was then applied to directly investigate granule recruitment to the plasma membrane. Silencing of myosin 5a inhibited granule recruitment during late phase of insulin secretion. In conclusion, we propose a model where insulin granules are transported through the actin network via both myosin 5a-mediated transport and via passive diffusion, with the former playing the major role during stimulatory conditions.     

Behavior and Properties of Mature Lytic Granules at the Immunological Synapse of Human Cytotoxic T Lymphocytes

Killing of virally infected cells or tumor cells by cytotoxic T lymphocytes requires targeting of lytic granules to the junction between the CTL and its target. We used whole-cell patch clamp to measure the cell capacitance at fixed intracellular [Ca²⁺] to study fusion of lytic granules in human CTLs. Expression of a fluorescently labeled human granzyme B construct allowed identification of lytic granule fusion using total internal reflection fluorescence microscopy. In this way capacitance steps due to lytic granule fusion were identified. Our goal was to determine the size of fusing lytic granules and to describe their behavior at the plasma membrane. On average, 5.02 ± 3.09 (mean ± s.d.) lytic granules were released per CTL. The amplitude of lytic granule fusion events was ~ 3.3 fF consistent with a diameter of about 325 nm. Fusion latency was biphasic with time constants of 15.9 and 106 seconds. The dwell time of fusing lytic granules was exponentially distributed with a mean dwell time of 28.5 seconds. Fusion ended in spite of the continued presence of granules at the immune synapse. The mobility of fusing granules at the membrane was indistinguishable from that of lytic granules which failed to fuse. While dwelling at the plasma membrane lytic granules exhibit mobility consistent with docking interspersed with short periods of greater mobility. The failure of lytic granules to fuse when visible in TIRF at the membrane may indicate that a membrane-confined reaction is rate limiting.     

Exocytosis of single chromaffin granules in cell-free inside-out membrane patches

In chromaffin cells, exocytosis of single granules and properties of the fusion pore--the first connection between vesicular lumen and extracellular space --can be studied by cell-attached patch amperometry, which couples patch-clamp capacitance measurements with simultaneous amperometric recordings of transmitter release. Here we have studied exocytosis of single chromaffin granules and endocytosis of single vesicles in cell-free inside-out membrane patches by patch capacitance measurements and patch amperometry. We excised patches from chromaffin cells by using methods developed for studying properties of single ion channels. With low calcium concentrations in the pipette and bath, the patches showed no spontaneous exocytosis, but exocytosis could be induced in some patches by applying calcium to the cytoplasmic side of the patch. Exocytosis was also stimulated by calcium entry through the patch membrane. Initial conductances of the fusion pore were undistinguishable in cell-attached and excised patch recordings, but the subsequent pore expansion was slower in excised patches. The properties of exocytotic fusion pores in chromaffin cells are very similar to those observed in mast cells and granulocytes. Excised patches provide a tool with which to study the mechanisms of fusion pore formation and endocytosis in vitro.     

Evaluation of the electrostatic field strength at the site of exocytosis in adrenal chromaffin cells.

Exocytosis in secretory cells consists of release from intracellular storage granules directly into the extracellular space via fusion of the granule membrane with the plasma membrane of the cell. It is considered here as comprising two distinct processes. One is the close apposition of granule and plasma membranes. The other arises from interactions between the two membranes during the process of apposition, leading to the formation of a fusion pore. In the following it is shown for the case of the adrenal medullary chromaffin cell that the fusion pore can be ascribed to electroporation of the granule membrane, triggered by the strong electric field existing at the site of exocytosis. Based on an electric surface charge model of the cytoplasmic side of the plasma membrane, resulting from the negatively charged phosphatidylserine groups, it is found that the electrostatic field strength at the site of exocytosis reaches values on the order of 10(8) V/m at small intermembrane distances of 3 nm and lower. The field strength increases with the size of the disc-shaped plasma membrane region generating the electric field, reaching an approximate limit for a radius of 10 nm, at a surface charge density of 5.4 x 10(-2) C/m2. According to previous experimental evaluations of threshold field strength, this field is sufficiently strong to cause membrane electroporation. This step is a precondition for the subsequent membrane fusion during the ongoing process of apposition, leading to secretion.     

VAMP8-dependent fusion of recycling endosomes with the plasma membrane facilitates T lymphocyte cytotoxicity

Cytotoxic T lymphocytes (CTLs) eliminate infected and neoplastic cells through directed release of cytotoxic granule contents. Although multiple SNARE proteins have been implicated in cytotoxic granule exocytosis, the role of vesicular SNARE proteins, i.e., vesicle-associated membrane proteins (VAMPs), remains enigmatic. VAMP8 was posited to represent the cytotoxic granule vesicular SNARE protein mediating exocytosis in mice. In primary human CTLs, however, VAMP8 colocalized with Rab11a-positive recycling endosomes. Upon stimulation, these endosomes rapidly trafficked to and fused with the plasma membrane, preceding fusion of cytotoxic granules. Knockdown of VAMP8 blocked both recycling endosome and cytotoxic granule fusion at immune synapses, without affecting activating signaling. Mechanistically, VAMP8-dependent recycling endosomes deposited syntaxin-11 at immune synapses, facilitating assembly of plasma membrane SNARE complexes for cytotoxic granule fusion. Hence, cytotoxic granule exocytosis is a sequential, multivesicle fusion process requiring VAMP8-mediated recycling endosome fusion before cytotoxic granule fusion. Our findings imply that secretory granule exocytosis pathways in other cell types may also be more complex than previously appreciated.     

Palmitoylation-defective asialoglycoprotein receptors are normal in their cellular distribution and ability to bind ligand,but are defective in ligand uptake and degradation

The examination of insulin exocytosis at the single cell level by conventional electrophysiologic and amperometric methods possesses inherent limitations, and may not accurately reflect the morphologic events of exocytosis of the insulin granule. To overcome some of these limitations, we show by epifluorescent microscopy of a fluorescent dye, FM1-43, its incorporation into the plasma membrane and oncoming insulin granules undergoing exocytosis, and their core proteins. Using this method, we tracked exocytosis in real-time in insulinoma INS-1 and single rat islet beta cells in response to KCl and glucose. We observed both single transient and multi-stepwise increases in membrane FM1-43 fluorescence, suggesting single granule exocytosis as well as sequential and compound exocytosis, respectively. Confocal microscopy of nonpermeabilized cells shows that some of the exocytosed insulin granules labeled by the FM1-43 dye could also be labeled with insulin antibodies, suggesting prolonged openings of the fusion pores and slow dissolution of the granule core proteins on the membrane surface.     

Immunocytochemical localization of factor VIII/von Willebrand factor antigen in human platelets

Specific antibodies against anti-human FVIII/vW protein were isolated by affinity chromatography on glutaraldehyde-activated gel (Ultrogel AcA22). They were coupled directly with peroxidase or visualized with anti-rabbit IgG (sheep)-peroxidase (Institut Pasteur). Fab fragments of the same specific antibodies were prepared to enhance the intracellular penetration and coupled to peroxidase. In washed human platelets, staining was observed on the plasma membrane and in the canalicular system, whereas in previous studies whole specific antibodies incubated with fixed platelets showed the labeling only on the plasma membrane. After thrombin activation, the release of granules containing FVIII/vW protein was better visualized in the surface canalicular system. This localization was discussed in regard to the exocytosis process: membrane fusion, granule labeling.