Actin dynamics during Ca2+-dependent exocytosis of endothelial Weibel-Palade bodies

Weibel-Palade bodies (WPBs) are specialized secretory organelles of endothelial cells that serve important functions in the response to inflammation and vascular injury. WPBs actively respond to different stimuli by regulated exocytosis leading to full or selective release of their contents. Cellular conditions and mechanisms that distinguish between these possibilities are only beginning to emerge. To address this we analyzed dynamic rearrangements of the actin cytoskeleton during histamine-stimulated, Ca²⁺-dependent WPB exocytosis. We show that most WPB fusion events are followed by a rapid release of von-Willebrand factor (VWF), the large WPB cargo, and that this occurs concomitant with a softening of the actin cortex by the recently described Ca²⁺-dependent actin reset (CaAR). However, a considerable fraction of WPB fusion events is characterized by a delayed release of VWF and observed after the CaAR reaction peak. These delayed VWF secretions are accompanied by an assembly of actin rings or coats around the WPB post-fusion structures and are also seen following direct elevation of intracellular Ca²⁺ by plasma membrane wounding. Actin ring/coat assembly at WPB post-fusion structures requires Rho GTPase activity and is significantly reduced upon expression of a dominant-active mutant of the formin INF2 that triggers a permanent CaAR peak-like sequestration of actin to the endoplasmic reticulum. These findings suggest that a rigid actin cortex correlates with a higher proportion of fused WPB which assemble actin rings/coats most likely required for efficient VWF expulsion and/or stabilization of a WPB post-fusion structure.This article is part of a Special Issue entitled: ECS Meeting edited by Claus Heizmann, Joachim Krebs and Jacques Haiech.     

Actin is not an essential component in the mechanism of calcium-triggered vesicle fusion

Actin has been suggested as an essential component in the membrane fusion stage of exocytosis. In some model systems disruption of the actin filament network associated with exocytotic membranes results in a decrease in secretion. Here we analyze the fast Ca2+-triggered membrane fusion steps of regulated exocytosis using a stage-specific preparation of native secretory vesicles (SV) to directly test whether actin plays an essential role in this mechanism. Although present on secretory vesicles, selective pharmacological inhibition of actin did not affect the Ca2+-sensitivity, extent, or kinetics of membrane fusion, nor did the addition of exogenous actin or an anti-actin antibody. There was also no discernable affect on inter-vesicle contact (docking). Overall, the results do not support a direct role for actin in the fast, Ca2+-triggered steps of regulated membrane fusion. It would appear that actin acts elsewhere within the exocytotic cycle.     

BLOC-2 subunit HPS6 deficiency affects the tubulation and secretion of von Willebrand factor from mouse endothelial cells

Hermansky-Pudlak syndrome(HPS) is a recessive disorder with bleeding diathesis, which has been linked to platelet granule defects. Both platelet granules and endothelial Weibel-Palade bodies(WPBs)are members of lysosome-related organelles(LROs) whose formation is regulated by HPS protein associated complexes such as BLOC(biogenesis of lysosome-related organelles complex)-1,-2,-3, AP-3(adaptor protein complex-3) and HOPS(homotypic fusion and protein sorting complex). Von Willebrand factor(VWF) is critical to hemostasis, which is stored in a highly-multimerized form as tubules in the WPBs. In this study, we found the defective, but varying, release of VWF into plasma after desmopressin(DDAVP) stimulation in HPS1(BLOC-3 subunit), HPS6(BLOC-2 subunit), and HPS9(BLOC-1 subunit)deficient mice. In particular, VWF tubulation, a critical step in VWF maturation, was impaired in HPS6 deficient WPBs. This likely reflects a defective endothelium, contributing to the bleeding tendency in HPS mice or patients. The differentially defective regulated release of VWF in these HPS mouse models suggests the need for precise HPS genotyping before DDAVP administration to HPS patients.     

Role of actin in regulated exocytosis and compensatory membrane retrieval: insights from an old acquaintance

This review summarizes new insights into the role of the actin cytoskeleton in exocytosis and compensatory membrane retrieval from mammalian regulated secretory cells. Data from our lab and others now indicate that the actin cytoskeleton is involved in exocytosis both as a negative regulator of membrane fusion under resting conditions and as a facilitator of movement of secretory granules to their site of fusion with the apical plasmalemma. Coating of docked secretory granules with actin filaments correlates with the dissociation of secretory-granule-associated rab3D, pointing out a novel role for rab proteins in modulating the actin cytoskeleton during regulated exocytosis. Compensatory membrane retrieval following regulated exocytosis is also critically dependent on the actin cytoskeleton both in initiating the formation of clathrin-coated retrieval vesicles and subsequent trafficking back into the cell. We propose that insertion of secretory granule membrane into the plasmalemma initiates a trigger for membrane retrieval, possibly by exposing sites where proteins involved in compensatory membrane retrieval are assembled. The results summarized in this review were derived primarily from investigations on the pancreatic acinar cell, an old friend who is providing modern wisdom not attainable in other simpler systems.     

Dynamic regulation of the large exocytotic fusion pore in pancreatic acinar cells

Loss of granule content during exocytosis requires the opening of a fusion pore between the secretory granule and plasma membrane. In a variety of secretory cells, this fusion pore has now been shown to subsequently close. However, it is still unclear how pore closure is physiologically regulated and contentious as to how closure relates to granule content loss. Here, we examine the behavior of the fusion pore during zymogen granule exocytosis in pancreatic acinar cells. By using entry of high-molecular-weight dyes from the extracellular solution into the granule lumen, we show that the fusion pore has a diameter of 29-55 nm. We further show that by 5 min after granule fusion, many granules have a closed fusion pore with evidence indicating that pore closure is a prelude to endocytosis and that in granules with a closed fusion pore the chymotrypsinogen content is low. Finally, we show that latrunculin B treatment promotes pore closure, suggesting F-actin affects pore dynamics. Together, our data do not support the classical view in acinar cells that exocytosis ends with granule collapse. Instead, for many granules the fusion pore closes, probably as a transition to endocytosis, and likely involving an F-actin-dependent mechanism.     

Vesicle-associated membrane protein 8 (VAMP8) is a SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) selectively required for sequential granule-to-granule fusion

Compound exocytosis is found in many cell types and is the major form of regulated secretion in acinar and mast cells. Its key characteristic is the homotypic fusion of secretory granules. These then secrete their combined output through a single fusion pore to the outside. The control of compound exocytosis remains poorly understood. Although soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) such as syntaxin 2, SNAP23 (synaptosome-associated protein of 23 kDa), and SNAP25 have been suggested to play a role, none has been proven. Vesicle-associated membrane protein 8 (VAMP8) is a SNARE first associated with endocytic processes but more recently has been suggested as an R-SNARE in regulated exocytosis. Secretion in acinar cells is reduced when VAMP8 function is inhibited and is less in VAMP8 knock-out mice. Based on electron microscopy experiments, it was suggested that VAMP8 may be involved in compound exocytosis. Here we have tested the hypothesis that VAMP8 controls homotypic granule-to-granule fusion during sequential compound exocytosis. We use a new assay to distinguish primary fusion events (fusion with the cell membrane) from secondary fusion events (granule-granule fusion). Our data show the pancreatic acinar cells from VAMP8 knock-out animals have a specific reduction in secondary granule fusion but that primary granule fusion is unaffected. Furthermore, immunoprecipitation experiments show syntaxin 2 association with VAMP2, whereas syntaxin 3 associates with VAMP8. Taken together our data indicate that granule-to-granule fusion is regulated by VAMP8 containing SNARE complexes distinct from those that regulate primary granule fusion.     

Temperature-dependence of Weibel-Palade body exocytosis and cell surface dispersal of von Willebrand factor and its propolypeptide

Background

Weibel-Palade bodies (WPB) are endothelial cell (EC) specific secretory organelles containing Von Willebrand factor (VWF). The temperature-dependence of Ca²⁺-driven WPB exocytosis is not known, although indirect evidence suggests that WPB exocytosis may occur at very low temperatures. Here we quantitatively analyse the temperature-dependence of Ca²⁺-driven WPB exocytosis and release of secreted VWF from the cell surface of ECs using fluorescence microscopy of cultured human ECs containing fluorescent WPBs.

Principal Findings

Ca²⁺-driven WPB exocytosis occurred at all temperatures studied (7–37°C). The kinetics and extent of WPB exocytosis were strongly temperature-dependent: Delays in exocytosis increased from 0.92 s at 37°C to 134.2 s at 7°C, the maximum rate of WPB fusion decreased from 10.0±2.2 s⁻¹ (37°C) to 0.80±0.14 s⁻¹ (7°C) and the fractional extent of degranulation of WPBs in each cell from 67±3% (37°C) to 3.6±1.3% (7°C). A discrepancy was found between the reduction in Ca²⁺-driven VWF secretion and WPB exocytosis at reduced temperature; at 17°C VWF secretion was reduced by 95% but WPB exocytosis by 75–80%. This discrepancy arises because VWF dispersal from sites of WPB exocytosis is largely prevented at low temperature. In contrast VWF-propolypeptide (proregion) dispersal from WPBs, although slowed, was complete within 60–120 s. Novel antibodies to the cleaved and processed proregion were characterised and used to show that secreted proregion more accurately reports the secretion of WPBs at sub-physiological temperatures than assay of VWF itself.

Conclusions

We report the first quantitative analysis of the temperature-dependence of WPB exocytosis. We provide evidence; by comparison of biochemical data for VWF or proregion secretion with direct analysis of WPB exocytosis at reduced temperature, that proregion is a more reliable marker for WPB exocytosis at reduced temperature, where VWF-EC adhesion is increased.     

How to roll an endothelial cigar: the biogenesis of Weibel-Palade bodies

Weibel-Palade bodies (WPB) are the regulated secretory organelles of endothelial cells. These cigar-shaped membrane-bound structures function in both hemostasis and inflammation but their biogenesis is poorly understood. Here, we review what is currently known about their formation. The content of WPBs is dominated by the hemostatic factor von Willebrand factor (VWF), whose complex biogenesis ends in the formation of high molecular weight multimers. VWF is also organized into proteinaceous tubules which underlie the striated interior of WPBs as seen in the EM. VWF expression is necessary for formation of WPBs, and its heterologous expression can even lead to the specific recruitment of WPB membrane proteins, including the leukocyte receptor P-selectin, the tetraspanin CD63, and Rab27a. Unusually, the VWF propeptide is implicated in the biogenesis of WPBs, being essential for formation of the storage compartment. The elongation of the cigars and the formation of the tubules are determined by non-covalent interactions between pro- and mature VWF proteins. Surprisingly, high molecular weight multimers seem neither necessary nor sufficient to trigger formation of a storage compartment, and do not seem to have any role in WPB biogenesis. Von Willebrand's disease, usually caused by mutations within VWF, has provided many of the insights into the way in which VWF drives the formation of these organelles.     

Acrosomal exocytosis, a special type of regulated secretion

The acrosome is a single secretory granule present in the head of mammalian--and other animal groups--sperm. Secretion of this granule is an absolute requirement for physiological fertilization. Acrosome exocytosis is a synchronized and tightly regulated all-or-nothing process, with no recycling of membranes. In the last few years, it has been shown that acrosomal exocytosis is mediated by a molecular mechanism that is homologous to that reported in the secretion of neuroendocrinal cells. Moreover, because of its particular characteristics, acrosomal exocytosis is a unique mammalian model for the study of the different steps of the membrane fusion cascade. Combining results in intact and permeabilized sperm, the following sequence of events has been proposed. In resting sperm, SNARE proteins are locked in inactive cis complexes. Sperm activation causes a calcium increase in the cytoplasm that promotes the production of cAMP and activates Rab3A. Afterwards, NSF and alphaSNAP disassemble cis complexes and the free SNAREs are then able to reassemble in loose trans complexes. Membrane fusion is arrested at this stage until calcium is released from inside the acrosome by inositol 1,4,5-trisphosphate-sensitive calcium channels to trigger the final steps of membrane fusion, which require fully assembled trans SNARE complexes and the calcium sensor synaptotagmin. This working model is still incomplete and tentative. Its improvement will be important to share light on this and other processes of regulated exocytosis. Moreover, it will bring new perspectives into the field of sperm-related fertility and sterility.     

Widespread association of annexin II with intracellular membrane systems and involvement of annexin II in granule--granule fusion in addition to granule--plasma membrane fusion in anterior pituitary cells

The subcellular localization in anterior pituitary secretory cells of annexin II, one of the Ca2+-dependent phospholipid-binding proteins, was examined by immunohistochemistry and immunoelectron microscopy. Annexin II was associated with the plasma membrane, the membranes of secretory granules and cytoplasmic organelles, such as rough endoplasmic reticulum, mitochondria and vesicles, and with the nuclear envelope. Annexin II was frequently detected at the contact sites of secretory granules with other granules and with the plasma membrane. The anterior pituitary and adrenal medulla were treated with Clostridium perfringens enterotoxin, which induces Ca2+ influx, and examined under an electron microscope. The anterior pituitary cells showed multigranular exocytosis, i.e. multiple fusions of secretory granules with each other and with the plasma membrane, but adrenal chromaffin cells, which lack annexin II on the granule membranes, never showed granule--granule fusion and only single granule exocytosis. From these results, we conclude that, in anterior pituitary secretory cells, annexin II is involved in granule--granule fusion in addition to granule--plasma membrane fusion. © 1998 Chapman & Hall     

Aftiphilin and gamma-synergin are required for secretagogue sensitivity of Weibel-Palade bodies in endothelial cells

Formation of secretory organelles requires the coupling of cargo selection to targeting into the correct exocytic pathway. Although the assembly of regulated secretory granules is driven in part by selective aggregation and retention of content, we recently reported that adaptor protein-1 (AP-1) recruitment of clathrin is essential to the initial formation of Weibel-Palade bodies (WPBs) at the trans-Golgi network. A selective co-aggregation process might include recruitment of components required for targeting to the regulated secretory pathway. However, we find that acquisition of the regulated secretory phenotype by WPBs in endothelial cells is coupled to but can be separated from formation of the distinctive granule core by ablation of the AP-1 effectors aftiphilin and γ-synergin. Their depletion by small interfering RNA leads to WPBs that fail to respond to secretagogue and release their content in an unregulated manner. We find that these non-responsive WPBs have density, markers of maturation, and highly multimerized von Willebrand factor similar to those of wild-type granules. Thus, by also recruiting aftiphilin/γ-synergin in addition to clathrin, AP-1 coordinates formation of WPBs with their acquisition of a regulated secretory phenotype.     

Bacterial toxins: useful for studying G-proteins implicated in the mechanism of exocytosis in neuroendocrine cells

In neuroendocrine cells, regulated exocytosis is a multistep process that comprises the recruitment and priming of secretory granules, their docking to the exocytotic sites, and the subsequent fusion of granules with the plasma membrane leading to the release of secretory products into the extracellular space. Using bacterial toxins which specially inactivate subsets of G proteins, we were able to demonstrate that both trimeric and monomeric G proteins directly control the late stages of exocytosis in chromaffin cells. Indeed, in secretagogue-stimulated chromaffin cells, the subplasmalemmal actin cytoskeleton undergoes a specific reorganization that is a prerequisite for exocytosis. Our results suggest that a granule-bound trimeric Go protein controls the actin network surrounding secretory granules through a pathway involving the GTPase RhoA and a downstream phosphatidylinositol 4-kinase. Furthermore, the GTPase Cdc42 plays a active role in exocytosis, most likely by providing specific actin structures to the late docking and/or fusion steps. We propose that G proteins tightly control secretion in neuroendocrine cells by coupling the actin cytoskeleton to the sequential steps underlying membrane trafficking at the site of exocytosis. Our data highlight the use of bacterial toxins, which proved to be powerful tools to dissect the exocytotic machinery at the molecular level.     

Proteomic screen identifies IGFBP7 as a novel component of endothelial cell-specific Weibel-Palade bodies

Vascular endothelial cells contain unique storage organelles, designated Weibel-Palade bodies (WPBs), that deliver inflammatory and hemostatic mediators to the vascular lumen in response to agonists like thrombin and vasopressin. The main component of WPBs is von Willebrand factor (VWF), a multimeric glycoprotein crucial for platelet plug formation. In addition to VWF, several other components are known to be stored in WPBs, like osteoprotegerin, monocyte chemoattractant protein-1 and angiopoetin-2 (Ang-2). Here, we used an unbiased proteomics approach to identify additional residents of WPBs. Mass spectrometry analysis of purified WPBs revealed the presence of several known components such as VWF, Ang-2, and P-selectin. Thirty-five novel candidate WPB residents were identified that included insulin-like growth factor binding protein-7 (IGFBP7), which has been proposed to regulate angiogenesis. Immunocytochemistry revealed that IGFBP7 is a bona fide WPB component. Cotransfection studies showed that IGFBP7 trafficked to pseudo-WPB in HEK293 cells. Using a series of deletion variants of VWF, we showed that targeting of IGFBP7 to pseudo-WPBs was dependent on the carboxy-terminal D4-C1-C2-C3-CK domains of VWF. IGFBP7 remained attached to ultralarge VWF strings released upon exocytosis of WPBs under flow. The presence of IGFBP7 in WPBs highlights the role of this subcellular compartment in regulation of angiogenesis.     

Vesicular trafficking through cortical actin during exocytosis is regulated by the Rab27a effector JFC1/Slp1 and the RhoA-GTPase-activating protein Gem-interacting protein

Cytoskeleton remodeling is important for the regulation of vesicular transport associated with exocytosis, but a direct association between granular secretory proteins and actin-remodeling molecules has not been shown, and this mechanism remains obscure. Using a proteomic approach, we identified the RhoA-GTPase-activating protein Gem-interacting protein (GMIP) as a factor that associates with the Rab27a effector JFC1 and modulates vesicular transport and exocytosis. GMIP down-regulation induced RhoA activation and actin polymerization. Importantly, GMIP-down-regulated cells showed impaired vesicular transport and exocytosis, while inhibition of the RhoA-signaling pathway induced actin depolymerization and facilitated exocytosis. We show that RhoA activity polarizes around JFC1-containing secretory granules, suggesting that it may control directionality of granule movement. Using quantitative live-cell microscopy, we show that JFC1-containing secretory organelles move in areas near the plasma membrane deprived of polymerized actin and that dynamic vesicles maintain an actin-free environment in their surroundings. Supporting a role for JFC1 in RhoA inactivation and actin remodeling during exocytosis, JFC1 knockout neutrophils showed increased RhoA activity, and azurophilic granules were unable to traverse cortical actin in cells lacking JFC1. We propose that during exocytosis, actin depolymerization commences near the secretory organelle, not the plasma membrane, and that secretory granules use a JFC1- and GMIP-dependent molecular mechanism to traverse cortical actin.     

Selective recapture of secretory granule components after full collapse exocytosis in neuroendocrine chromaffin cells

In secretory cells, calcium-regulated exocytosis is rapidly followed by compensatory endocytosis. Neuroendocrine cells secrete hormones and neuropeptides through various modes of exo-endocytosis, including kiss-and-run, cavicapture and full-collapse fusion. During kiss-and-run and cavicapture modes, the granule membrane is maintained in an omega shape, whereas it completely merges with the plasma membrane during full-collapse mode. As the composition of the granule membrane is very different from that of the plasma membrane, a precise sorting process of granular proteins must occur. However, the fate of secretory granule membrane after full fusion exocytosis remains uncertain. Here, we investigated the mechanisms governing endocytosis of collapsed granule membranes by following internalization of antibodies labeling the granule membrane protein, dopamine-β-hydroxylase (DBH) in cultured chromaffin cells. Using immunofluorescence and electron microscopy, we observed that after full collapse, DBH remains clustered on the plasma membrane with other specific granule markers and is subsequently internalized through vesicular structures composed mainly of granule components. Moreover, the incorporation of this recaptured granule membrane into an early endosomal compartment is dependent on clathrin and actin. Altogether, these results suggest that after full collapse exocytosis, a selective sorting of granule membrane components is facilitated by the physical preservation of the granule membrane entity on the plasma membrane.     

Endothelial cell confluence regulates Weibel-Palade body formation

Secretory granules called Weibel-Palade bodies (WPBs) containing Von Willebrand factor (VWF) are characteristic of the mammalian endothelium. We hypothesized that vascular-specific antigens such as VWF are linked to endothelial identity and proliferation in vitro. To test this idea, the cellular accumulation of VWF in WPBs was monitored as a function of cell proliferation, confluence and passage number in human umbilical vein endothelial cells (HUVECs). We found that as passage number increased the percentage of cells containing VWF in WPBs was reduced significantly, whilst the protein was still detected within the secretory pathway at all times. However, the endothelial-specific marker protein, PECAM-1, is present on all cells even when WPBs are absent, indicating partial maintenance of endothelial identity. Biochemical studies show that a significant pool of immature pro-VWF can be detected in sub-confluent HUVECs; however, a larger pool of mature, processed VWF is detected in confluent cells. Newly synthesized VWF must thus be differentially sorted and packaged along the secretory pathway in semi-confluent versus confluent endothelial cells. Our studies thus show that WPB formation is linked to the formation of a confluent endothelial monolayer.     

Endothelial cell confluence regulates Weibel-Palade body formation

Secretory granules called Weibel-Palade bodies (WPBs) containing Von Willebrand factor (VWF) are characteristic of the mammalian endothelium. We hypothesized that vascular-specific antigens such as VWF are linked to endothelial identity and proliferation in vitro. To test this idea, the cellular accumulation of VWF in WPBs was monitored as a function of cell proliferation, confluence and passage number in human umbilical vein endothelial cells (HUVECs). We found that as passage number increased the percentage of cells containing VWF in WPBs was reduced significantly, whilst the protein was still detected within the secretory pathway at all times. However, the endothelial-specific marker protein, PECAM-1, is present on all cells even when WPBs are absent, indicating partial maintenance of endothelial identity. Biochemical studies show that a significant pool of immature pro-VWF can be detected in sub-confluent HUVECs; however, a larger pool of mature, processed VWF is detected in confluent cells. Newly synthesized VWF must thus be differentially sorted and packaged along the secretory pathway in semi-confluent versus confluent endothelial cells. Our studies thus show that WPB formation is linked to the formation of a confluent endothelial monolayer.     

Differential kinetics of cell surface loss of von Willebrand factor and its propolypeptide after secretion from Weibel-Palade bodies in living human endothelial cells

The time course for cell surface loss of von Willebrand factor (VWF) and the propolypeptide of VWF (proregion) following exocytosis of individual Weibel-Palade bodies (WPBs) from single human endothelial cells was analyzed. Chimeras of enhanced green fluorescent protein (EGFP) and full-length pre-pro-VWF (VWF-EGFP) or the VWF propolypeptide (proregion-EGFP) were made and expressed in human umbilical vein endothelial cells. Expression of VWF-EGFP or proregion-EGFP resulted in fluorescent rod-shaped organelles that recruited the WPB membrane markers P-selectin and CD63. The WPB secretagogue histamine evoked exocytosis of these fluorescent WPBs and extracellular release of VWF-EGFP or proregion-EGFP. Secreted VWF-EGFP formed distinctive extracellular patches of fluorescence that were labeled with an extracellular antibody to VWF. The half-time for dispersal of VWF-EGFP from extracellular patches was 323.5 +/- 146.2 s (+/-S.D., n = 20 WPBs). In contrast, secreted proregion-EGFP did not form extracellular patches but dispersed rapidly from its site of release. The half-time for dispersal of proregion-EGFP following WPB exocytosis was 2.98 +/- 1.88 s (+/-S.D., n = 32 WPBs). The slow rate of loss of VWF-EGFP is consistent with the adhesive nature of this protein for the endothelial membrane. The much faster rate of loss of proregion-EGFP indicates that this protein does not interact strongly with extracellular VWF or the endothelial membrane and consequently may not play an adhesive role at the endothelial cell surface.     

Motion matters: secretory granule motion adjacent to the plasma membrane and exocytosis

Total internal reflection fluorescence microscopy was used to monitor changes in individual granule motions related to the secretory response in chromaffin cells. Because the motions of granules are very small (tens of nanometers), instrumental noise in the quantitation of granule motion was taken into account. ATP and Ca2+, both of which prime secretion before fusion, also affect granule motion. Removal of ATP in permeabilized cells causes average granule motion to decrease. Nicotinic stimulation causes a calcium-dependent increase in average granule motion. This effect is more pronounced for granules that undergo exocytosis than for those that do not. Fusion is not preceded by a reduction in mobility. Granules sometimes move 100 nm or more up to and within a tenth of a second before fusion. Thus, the jittering motion of granules adjacent to the plasma membrane is regulated by factors that regulate secretion and may play a role in secretion. Motion continues until shortly before fusion, suggesting that interaction of granule and plasma membrane proteins is transient. Disruption of actin dynamics did not significantly alter granule motion.     

Insight in the exocytotic process in chromaffin cells: regulation by trimeric and monomeric G proteins

Catecholamine secretion from chromaffin cells has been used for a long time as a general model to study exocytosis of large dense core secretory granules. Permeabilization and microinjection techniques have brought the possibility to dissect at the molecular level the multi-protein machinery involved in this complex physiological process. Regulated exocytosis comprises distinct and sequential steps including the priming of secretory granules, the formation of a docking complex between granules and the plasma membrane and the subsequent fusion of the granule with the plasma membrane. Key proteins involved in the exocytotic machinery have been identified. For instance, SNAREs which participate in the docking events in most intracellular transport steps along the secretory pathway, play a role in exocytosis in both neuronal and endocrine cells. However, in contrast to intracellular transport processes for which the highest fusion efficiency is required after correct targeting of the vesicles, the number of exocytotic events in activated secretory cells needs to be tightly controlled. We describe here the multistep control exerted by heterotrimeric and monomeric G proteins on the progression of secretory granules from docking to fusion and the molecular nature of some of their downstream effectors in neuroendocrine chromaffin cells.