Insulin binding and vesicular ingestion in capillary endothelium

Capillary endothelium can actively regulate vascular permeability of various serum proteins. Hormones such as insulin must interact with this capillary barrier in order to reach their respective target tissues. We have studied the binding and subsequent internalization of 125I-insulin in both native (freshly isolated) and primary cultured capillary endothelium derived from rat epididymal fat pads. Insulin association with the endothelium, internalization and degradation differed between freshly isolated and primary cultured capillaries. Specific binding in freshly isolated and cultured capillaries was temperature dependent, and was competitively inhibited in the presence of unlabelled insulin. Primary cultures of capillaries grown to confluence did not exhibit specific binding of insulin. Despite the lack of specific receptors for insulin, cultured cells vesicularly internalized insulin. Greater than 50% of the total associated insulin was not degraded by cultured endothelium. Morphological examinations using ferritin labelled insulin localized insulin associated to the capillary endothelial cell membrane and sequestered within pinocytotic vesicles. Incubation of freshly isolated capillaries with insulin stimulated the fluid phase endocytosis of 14C-sucrose; however, insulin had no effect on fluid phase endocytosis in cultured capillaries. These results indicate that capillary endothelium, isolated from rat epididymal fat, exhibit specific receptors for insulin. Binding of insulin to the capillary membrane is followed by internalization into cytoplasmic vesicles and partial degradation.     

Quantitative immunocytochemical studies of endogenous albumin in rat aortic endothelial and mesothelial cells

Endogenous albumin was revealed over cellular structures of rat ascendent aorta endothelia and mesothelium, with high resolution and specificity, by applying the protein A-gold immunocytochemical approach. This approach allows albumin distribution to be studied under steady-state conditions. The cellular layers evaluated were the aortic endothelium, the capillary endothelium (vasa vasorum), and the mesothelium externally lining the aorta at this level. Gold particles, revealing albumin antigenic sites, were preferentially located over plasmalemmal vesicles and intercellular clefts of endothelial and mesothelial cells, though with different labeling intensities. The interstitial space was also labeled. Morphometrical evaluation of plasmalemmal vesicles demonstrated a higher surface density for these structures in capillary endothelial cells (12%) compared with those in aortic endothelial (5%) and mesothelial cells (2%). Quantitation of gold labeling intensities over these structures revealed a higher labeling over plasmalemmal vesicles of capillary endothelium than over those of aortic endothelium and mesothelium. This result, together with the higher surface density of plasmalemmal vesicles found in capillary endothelium, suggest an important role of these structures in the transendothelial passage of endogenous albumin, particularly for capillary endothelium. On the other hand, labeling densities over mesothelial clefts were found to be higher than those of capillary and aortic endothelia. Results from this study concur with the proposal of a differential passage of albumin according to the cell lining considered, and suggest to a role for mesothelial intercellular clefts in contributing to the presence of albumin in interstitial spaces.     

Endocytosis and Exocytosis Events Regulate Vesicle Traffic in Endothelial Cells

We used water-soluble styryl pyridinium dyes that fluoresce at the membrane-water interface to study vesicle traffic in endothelial cells. Cultured endothelial cells derived from bovine and human pulmonary microvessels were incubated in styryl probes, washed to remove dye from the plasmalemmal outer face, and observed by digital fluorescence microscopy. Vesicles that derived from plasmalemma by endocytosis were filled with the styryl dye. These vesicles were distributed throughout the cytosol as numerous particles of heterogeneous diameter and brightness. Vesicle formation was activated 2-fold following addition of extracellular albumin whereas a control protein, immunoglobulin G, had no effect. Dye uptake was abrogated by labeling at low temperatures and inhibitors of phosphoinositide-3-kinase (PI 3-kinase). Tyrosine kinase inhibitors (genistein and herbimycin A) prevented the albumin-induced vesicle formation. Cytochalasin B prevented vesicle redistribution indicating involvement of actin filaments in translocation of endosomes away from sites of vesicle formation. Styryl dye was lost from cells by exocytosis as evident by the disappearance of discrete fluorescent particles. N-ethylmaleimide and botulinum toxin types A and B caused cells to accumulate increased number of vesicles suggesting that exocytosis was regulated by NSF-dependent SNARE mechanism. The results suggest that phosphoinositide metabolism regulates endocytosis in endothelial cells and that extracellular albumin activates endocytosis by a mechanism involving tyrosine phosphorylation, whereas exocytosis is a distinct process regulated by the SNARE machinery. The results support the hypothesis that albumin regulates its internalization and release in vascular endothelial cells via activation of specific endocytic and exocytic pathways.     

Filipin-sensitive caveolae-mediated transport in endothelium: reduced transcytosis, scavenger endocytosis, and capillary permeability of select macromolecules

Caveolae or noncoated plasmalemmal vesicles found in a variety of cells have been implicated in a number of important cellular functions including endocytosis, transcytosis, and potocytosis. Their function in transport across endothelium has been especially controversial, at least in part because there has not been any way to selectively inhibit this putative pathway. We now show that the ability of sterol binding agents such as filipin to disassemble endothelial noncoated but not coated plasmalemmal vesicles selectively inhibits caveolae-mediated intracellular and transcellular transport of select macromolecules in endothelium. Filipin significantly reduces the transcellular transport of insulin and albumin across cultured endothelial cell monolayers. Rat lung microvascular permeability to albumin in situ is significantly decreased after filipin perfusion. Conversely, paracellular transport of the small solute inulin is not inhibited in vitro or in situ. In addition, we show that caveolae mediate the scavenger endocytosis of conformationally modified albumins for delivery to endosomes and lysosomes for degradation. This intracellular transport is inhibited by filipin both in vitro and in situ. Other sterol binding agents including nystatin and digitonin also inhibit this degradative process. Conversely, the endocytosis and degradation of activated alpha 2- macroglobulin, a known ligand of the clathrin-dependent pathway, is not affected. Interestingly, filipin appears to inhibit insulin uptake by endothelium for transcytosis, a caveolae-mediated process, but not endocytosis for degradation, apparently mediated by the clathrin-coated pathway. Such selective inhibition of caveolae not only provides critical evidence for the role of caveolae in the intracellular and transcellular transport of select macromolecules in endothelium but also may be useful for distinguishing transport mediated by coated versus noncoated vesicles.     

Transcytosis in the epididymis studied by local arterial perfusion

Summary The transport of protein across the cells of the epididymal epithelium was studied using horseradish peroxidase. Transient vascular perfusion of the epididymis of the rat and golden hamster was achieved by pulsatile retrograde infusion into the testicular artery. Peroxidase was found in the interstitium and in the epithelium, located in vesicles, vacuoles and multivesicular bodies of principal, clear and apical cells. Similar findings were obtained in mice after systemic injection of the tracer. In the rat, discharge to the lumen was confirmed by the appearance of enzyme activity in luminal fluid from the caput epididymidis after local injection. The extent of transport amounted to no more than what has been considered leakage in physiological experiments, and the time-course of appearance complemented that found by electron microscopy. The level of transcytosis after pulsatile administration of peroxidase in vivo, as judged from the occurrence of tracer in the epithelium, was much less than that obtained during constant immersion in vitro. The protein was present in multivesicular bodies of principal cells and in vesicles of clear cells at short times after presentation in vitro, when it could not have arrived by endocytosis from the lumen. This suggests that routing of basal endocytic vesicles to the lysosomal apparatus occurs.     

The blood-brain barrier in a reptile, Anolis carolinensis

An electron microscopic study was made of the ultrastructure and permeability of the capillaries in the cerebral hemispheres of the lizard, Anolis carolinensis. The brain of Anolis is vascularized by a loop-type pattern consisting exclusively of arteriovenous capillary loops. The ultrastructure of the endothelium and the arrangement of the various layers from the capillary lumen to the central nervous tissue is similar to that of mammals. The endothelial cells form a continuous layer around the lumen and are joined by tight interendothelial junctions. The basal lamina of the endothelium is also continuous and encloses pericyte processes. The cells of the nervous tissue rest directly on the basal lamina of the capillary and are separated from each other by a 200 Å space. Intravenously injected horseradish peroxidase (MW 40,000) and ferritin (MW 500,000) were used to study the permeability of the capillaries. The entry of horseradish peroxidase and ferritin into the intercellular spaces of the brain is restricted by the tightness of the interendothelial junctions. No vesicular transport of either tracer occurs; however, ferritin does enter the endothelial cells in vacuoles. No tracer molecules are present in the basal lamina, pericytes, or nervous tissue. The different responses of the endothelial cell to the tracers used in this study suggest that endocytotic activities of endothelial cells involve different processes. Vacuoles formed by marginal folds, vacuoles formed by endothelial surface projections or deep invaginations of the plasma membrane, 600–800 Å vesicles, and coated vesicles all seem to differ in the nature of the substances which they endocytose.     

Fluid-phase endocytosis by intrahepatic bile duct epithelial cells isolated from normal rat liver

Although recent data from our laboratory have established the occurrence of receptor-mediated endocytosis in intrahepatic bile duct epithelial cells (IBDEC) isolated from normal rat liver, no studies have assessed the role of isolated IBDEC in fluid-phase endocytosis. Therefore, to determine if IBDEC participate in fluid-phase endocytosis, we incubated morphologically polar doublets of IBDEC isolated from normal rat liver with horseradish peroxidase (HRP, 5 mg/ml), a protein internalized by fluid-phase endocytosis, and determined its intracellular distribution by electron microscopic cytochemistry. Pulse-chase studies using quantitative morphometry were also performed to assess the fate of HRP after internalization. After incubation at 37 degrees C, IBDEC internalized HRP exclusively at the apical (i.e., luminal) domain of their plasma membrane; internalization was completely blocked at 4 degrees C. After internalization, HRP was seen in acid phosphatase-negative vesicles and in acid phosphatase-positive multivesicular bodies (i.e., secondary lysosomes). Small acid phosphatase-negative vesicles containing HRP moved progressively from the apical to the basal domain of IBDEC. Pulse-chase studies showed that HRP was then discharged by exocytosis at the basolateral cell surface. These results demonstrate that IBDEC prepared from normal rat liver participate in fluid-phase endocytosis. After internalization, HRP either is routed to secondary lysosomes or undergoes exocytosis after transcytosis from the luminal to the basolateral cell surface. Our results suggest that IBDEC modify the composition of bile by internalizing both biliary proteins and fluid via endocytic mechanisms.     

Confocal imaging of xenobiotic transport across the blood-brain barrier

The brain capillary endothelium is a formidable barrier to entry of foreign chemicals into the central nervous system (CNS). For the most part it poorly distinguishes between therapeutics and neurotoxins and thus the blood-brain barrier both protects the brain from toxic chemicals and limits our ability to treat a variety of CNS disorders. Two elements underlie the barrier function of the brain capillary endothelium: 1). a physical barrier comprised of tight junctions, which form an effective seal to intercellular diffusion, and the cells themselves, which exhibit a low rate of endocytosis, and 2). a metabolic/active barrier, comprised of specific membrane transporters expressed by the endothelial cells. We have recently developed an experimental system based on confocal microscopy to study mechanisms of transport in freshly isolated brain capillaries. Here I review studies demonstrating a major role for the ATP-driven, xenobiotic export pump, p-glycoprotein, in barrier function and recent experiments showing that transient inhibition of pump function can have substantial benefit for chemotherapy in an animal model of brain cancer.     

Vesicle formation and trafficking in endothelial cells and regulation of endothelial barrier function

Endothelial barrier function is regulated in part by the transcellular transport of albumin and other macromolecules via endothelial caveolae (i.e., this process is defined as transcytosis). Using pulmonary microvascular endothelial cells, we have identified the specific interactions between a cell surface albumin-docking protein gp60 and caveolin-1 as well as components of the signaling machinery, heterotrimeric G protein (G(i))- and Src-family tyrosine kinase. Ligation of gp60 on the apical membrane induces the release of caveolae from the apical membrane and activation of endocytosis. The formed vesicles contain the gp60-bound albumin and also albumin and other solutes present in the fluid phase. Vesicles are transported in a polarized manner to the basolateral membrane, releasing their contents by exocytosis into the subendothelial space. The signaling functions of G(i) and Src are important in the release of caveolae from the plasma membrane. The Src-induced phosphorylation of caveolin-1 is crucial in regulating interactions of caveolin-1 with other components of the signaling machinery such as G(i), and key signaling entry of caveolae into the cytoplasm and endocytosis of albumin and other solutes. This review addresses the basis of transcytosis in endothelial cells, its central role as a determinant of endothelial barrier function, and signaling mechanisms involved in regulating fission of caveolae and trafficking of the formed vesicles from the luminal to abluminal side of the endothelial barrier.     

Synaptobrevin is essential for fast synaptic-vesicle endocytosis

Synaptobrevin-2 (VAMP-2), the major SNARE protein of synaptic vesicles, is required for fast calcium-triggered synaptic-vesicle exocytosis. Here we show that synaptobrevin-2 is also essential for fast synaptic-vesicle endocytosis. We demonstrate that after depletion of the readily releasable vesicle pool, replenishment of the pool is delayed by knockout of synaptobrevin. This delay was not from a loss of vesicles, because the total number of pre-synaptic vesicles, docked vesicles and actively recycling vesicles was unaffected. However, altered shape and size of the vesicles in synaptobrevin-deficient synapses suggests a defect in endocytosis. Consistent with such a defect, the stimulus-dependent endocytosis of horseradish peroxidase and fluorescent FM1-43 were delayed, indicating that fast vesicle endocytosis may normally be nucleated by a SNARE-dependent coat. Thus, synaptobrevin is essential for two fast synapse-specific membrane trafficking reactions: fast exocytosis for neurotransmitter release and fast endocytosis that mediates rapid reuse of synaptic vesicles.     

Lipid remodelling in neuroendocrine secretion

Neuroendocrine cells secrete hormones and polypeptides through a complex membrane trafficking process that involves the transport of specific organelles, called large dense core secretory granules, from the Golgi apparatus to specialised sites at the plasma membrane where these vesicles are successively exocytosed and recaptured by endocytosis through tightly coupled reactions. The minimal machinery required for exocytosis has been defined as SNARE proteins associated with few accessory proteins. On the other side, clathrin and dynamin constitute major components of some of the most important endocytotic pathways. Although many protein contributors of both exocytosis and endocytosis are now identified, their actual interplay is not well resolved. Furthermore, the necessary tight coupling of exocytosis and compensatory endocytosis to maintain membrane homeostasis in neuroendocrine cells is far from being understood. In this review, we focus on the more recently identified role of lipids in these important processes that are above all membrane remodelling events.     

Sweeping model of dynamin activity. Visualization of coupling between exocytosis and endocytosis under an evanescent wave microscope with green fluorescent proteins

Vesicle recycling through exocytosis and endocytosis is mediated by a coordinated cascade of protein-protein interactions. Previously, exocytosis and endocytosis were studied separately so that the coupling between them was understood only indirectly. We focused on the coupling of these processes by observing the secretory vesicle marker synaptobrevin and the endocytotic vesicle marker dynamin I tagged with green and red fluorescent proteins under an evanescent wave microscope in pheochromocytoma cells. In control cells, many synaptobrevin-expressing vesicles were found as fluorescent spots near the plasma membrane. Upon electrical stimulation, many of these vesicles showed an exocytotic response as a transient increase in fluorescence intensity followed by their disappearance. In contrast, fluorescent dynamin appeared as clusters increasing slowly in number upon stimulation. The clusters of fluorescent dynamin moved around beneath the plasma membrane for a significant distance. Simultaneous observations of green fluorescent dynamin and red fluorescent synaptobrevin indicated that more than 70% of the exocytotic responses of synaptobrevin had no immediate dynamin counterpart at the same site. From these findings it was concluded that dynamin-mediated recycling is not directly coupled to exocytosis but rather completed by a scanning movement of dynamin for the sites of invaginating membrane destined to endocytosis.     

Transient Expression of Iron Transport Proteins in the Capillary of the Developing Rat Brain

Iron is essential for normal brain function and its uptake in the developing rat brain peaks during the first two weeks after birth, prior to the formation of the blood–brain barrier (BBB). The first step of iron transport from the blood to the brain is transferrin receptor (TfR)-mediated endocytosis in the capillary endothelial cells. However, the subsequent step from the endothelium into interstitium has not been fully described. The goal of this study was to examine the expression of iron transport proteins by immunodetection and RT–PCR in the developing rat brain. Tf and TfR are transiently expressed in perivascular NG2+ cells of the capillary wall during the early postnatal weeks in the rat brain. However, MTP-1 and hephaestin were expressed in endothelial cells, but not in the NG2+ perivascular cells. Immunoblot analysis for these iron transfer proteins in the developing brain generally confirmed the immunochemical findings. Furthermore, the expression of Tf and TfR in the blood vessels precedes its expression in oligodendrocytes, the main iron-storing cells in the vertebrate brain. RT–PCR analysis for the primary culture of endothelial cells and pericytes revealed that Tf and TfR were highly expressed in the pericytes while MTP-1 and hephaestin were expressed in the endothelial cells. The specific expression of Tf and TfR in brain perivascular cells and MTP-1 and hephaestin in endothelial cells suggest the possibility that trafficking of elemental iron through perivascular cells may be instrumental in the distribution of iron in the developing central nervous system.     

Plasma membrane-associated vesicles in retinal capillaries of the rat

The structure and function of abluminal vesicles in endothelial cells of rat retinal capillaries was examined using glutaraldehyde-tannic acid fixation and the hemeproteins--horseradish peroxidase, microperoxidase, and lactoperoxidase--as tracers. Numerous vesicles, delimited by a tannic acid-positive membrane, were distributed along the abluminal front. Other vesicles were arranged in clusters and chains or tubule-like structures. Such vesicles were not found in the vicinity of the capillary lumen. When the retina was exposed to hemeproteins, either in vitro or after intravitreal injection, the abluminal vesicles became labeled with tracer reaction product. Apparently "free" vesicles and tubules seen in tangential sections through the basal lamina were also labeled, suggesting that they were in continuity with the plasma membrane in another plane of section. No enzyme reaction product was present in the capillary lumen. Peroxidase-positive multivesicular bodies were observed, suggesting that some protein was endocytosed and directed to lysosomes where it was presumably degraded. The results suggest that abluminal endothelial vesicles represent pits or invaginations of the plasma membrane and, as such, are not involved in the transendothelial transport of protein from the perivascular space to the capillary lumen. Tannic acid treatment revealed a population of similar vesicles associated with the plasma membrane of pericytes. After exposure to hemeproteins, enzyme reaction product was localized in these vesicles and in a few multivesicular bodies. The results suggest that the majority of these vesicles are in continuity with the plasma membrane and are not involved in endocytosis.     

Endothelial Progenitors Exist within the Kidney and Lung Mesenchyme

The renal endothelium has been debated as arising from resident hemangioblast precursors that transdifferentiate from the nephrogenic mesenchyme (vasculogenesis) and/or from invading vessels (angiogenesis). While the Foxd1-positive renal cortical stroma has been shown to differentiate into cells that support the vasculature in the kidney (including vascular smooth muscle and pericytes) it has not been considered as a source of endothelial cell progenitors. In addition, it is unclear if Foxd1-positive mesenchymal cells in other organs such as the lung have the potential to form endothelium. This study examines the potential for Foxd1-positive cells of the kidney and lung to give rise to endothelial progenitors. We utilized immunofluorescence (IF) and fluorescence-activated cell sorting (FACS) to co-label Foxd1-expressing cells (including permanently lineage-tagged cells) with endothelial markers in embryonic and postnatal mice. We also cultured FACsorted Foxd1-positive cells, performed in vitro endothelial cell tubulogenesis assays and examined for endocytosis of acetylated low-density lipoprotein (Ac-LDL), a functional assay for endothelial cells. Immunofluorescence and FACS revealed that a subset of Foxd1-positive cells from kidney and lung co-expressed endothelial cell markers throughout embryogenesis. In vitro, cultured embryonic Foxd1-positive cells were able to differentiate into tubular networks that expressed endothelial cell markers and were able to endocytose Ac-LDL. IF and FACS in both the kidney and lung revealed that lineage-tagged Foxd1-positive cells gave rise to a significant portion of the endothelium in postnatal mice. In the kidney, the stromal-derived cells gave rise to a portion of the peritubular capillary endothelium, but not of the glomerular or large vessel endothelium. These findings reveal the heterogeneity of endothelial cell lineages; moreover, Foxd1-positive mesenchymal cells of the developing kidney and lung are a source of endothelial progenitors that are likely critical to patterning the vasculature.     

Studies on the binding of a 32K rat epididymal protein to rat epididymal spermatozoa

A glycoprotein of molecular weight 32K has been isolated and purified from the rat caudal epididymal fluid by gel filtration, ion-exchange and affinity chromatography. The highly purified protein was labeled with radioactive iodine and the binding of the 125I-labeled 32K rat epididymal protein (REP) to washed rat caudal epididymal sperm was studied under various conditions. Scatchard plots of the binding data revealed two binding kinetics. One bound with high affinity (KD = 2.6 X 10(-10) ) but low capacity. The other bound with lower affinity (KD = 2.2 X 10(-9)M) but high capacity. The rate of binding of the labeled protein to sperm was dependent on the temperature of the incubation medium. At the scrotal temperature of 33 degrees C, maximal binding was obtained after 40 min. However, at 22 degrees C equilibrium state was reached after 90 min and at 0 degrees C, the equilibrium rate was not reached even after 120 min of incubation. Binding showed dependence on extracellular pH (optimal pH at 4) and ionic strength of the incubation medium. High ionic strength was found to inhibit binding of the 125I-labeled 32K REP to rat caudal epididymal sperm. Specific binding was abolished by 100-fold molar excess unlabeled 32K REP or by native rat caudal epididymal fluid proteins, but not by albumin or ovalbumin. This indicates high specificity of binding. This study has provided direct evidence for the interaction of an epididymal protein with epididymal spermatozoa.     

Visualization of the binding, endocytosis, and transcytosis of low- density lipoprotein in the arterial endothelium in situ

We investigated the interaction and transport of low-density lipoprotein (LDL) through the arterial endothelium in rat aorta and coronary artery, by perfusing in situ native, untagged human, and rat LDL. The latter was rendered electron-opaque after it interacted with the endothelial cell and was subsequently fixed within tissue. We achieved LDL electron-opacity by an improved fixation procedure using 3,3'-diaminobenzidine, and mordanting with tannic acid. The unequivocal identification of LDL was implemented by reacting immunocytochemically the perfused LDL with anti LDL-horseradish peroxidase conjugate. Results indicate that LDL is taken up and internalized through two parallel compartmented routes. (a) A relatively small amount of LDL is taken up by endocytosis via: (i) a receptor-mediated process (adsorptive endocytosis) that involved coated pits/vesicles, and endosomes, and, probably, (ii) a receptor-independent process (fluid endocytosis) carried out by a fraction of plasmalemmal vesicles. Both mechanisms bringing LDL to lysosomes supply cholesterol to the endothelial cell itself. (b) Most circulating LDL is transported across the endothelial cell by transcytosis via plasmalemmal vesicles which deliver LDL to the other cells of the vessel wall. Endocytosis is not enhanced by increasing LDL concentration, but the receptor-mediated internalization decreases at low temperature. Transcytosis is less modified by low temperature but is remarkably augmented at high concentration of LDL. While the endocytosis of homologous (rat) LDL is markedly more pronounced than that of heterologous (human) LDL, both types of LDL are similarly transported by transcytosis. These results indicate that the arterial endothelium possesses a dual mechanism for handling circulating LDL: by a high affinity process, endocytosis secures the endothelial cells' need for cholesterol; by a low-affinity nonsaturable uptake process, transcytosis supplies cholesterol to the other cells of the vascular wall, and can monitor an excessive accumulation of plasma LDL. Since in most of our experiments we used LDL concentrations above those found in normal rats, we presume that at low LDL concentrations saturable high-affinity uptake would be enhanced in relation to nonsaturable pathways.     

The effects of hydrogen sulfide on the processes of exo- and endocytosis of synaptic vesicles in the mouse motor nerve endings

The effects of sodium hydrosulfide (NaHS), the donor of hydrogen sulfide (H2S), on the exo/endocytosis cycle of synaptic vesicles in the motor nerve ending of the mouse diaphragm were studied using intracellular microelectrode technique and fluorescent microscopy. NaHS increased the frequency of miniature end-plate potentials (MEPPs), without changing their amplitude-time parameters. NaHS also increased the amplitude of the evoked postsynaptic responses during single stimulation (0.3 Hz), which was the evidence of the enhanced synaptic vesicle exocytosis. During high-frequency stimulation (50 Hz), NaHS induced more significant decline of neurotransmitter release, probably due to the lower rate of synaptic vesicle mobilization from recycling pool to exocytic sites. NaHS also decreased the uptake of the fluorescent endocytic dye FM 1–43, which indicated the reduced endocytosis of synaptic vesicles. Thus, the H₂S donor increases exocytosis and decreases the processes of synaptic vesicle endocytosis and mobilization in the mouse motor nerve ending.     

Exocytosis of catecholamine (CA)-containing and CA-free granules in chromaffin cells

Recent evidence suggests that endocytosis in neuroendocrine cells and neurons can be tightly coupled to exocytosis, allowing rapid retrieval from the plasma membrane of fused vesicles for future use. This can be a much faster mechanism for membrane recycling than classical clathrin-mediated endocytosis. During a fast exo-endocytotic cycle, the vesicle membrane does not fully collapse into the plasma membrane; nevertheless, it releases the vesicular contents through the fusion pore. Once the vesicle is depleted of transmitter, its membrane is recovered without renouncing its identity. In this report, we show that chromaffin cells contain catecholamine-free granules that retain their ability to fuse with the plasma membrane. These catecholamine-free granules represent 7% of the total population of fused vesicles, but they contributed to 47% of the fusion events when the cells were treated with reserpine for several hours. We propose that rat chromaffin granules that transiently fuse with the plasma membrane preserve their exocytotic machinery, allowing another round of exocytosis.     

High calcium concentrations shift the mode of exocytosis to the kiss-and-run mechanism

Exocytosis, the fusion of secretory vesicles with the plasma membrane to allow release of the contents of the vesicles into the extracellular environment, and endocytosis, the internalization of these vesicles to allow another round of secretion, are coupled. It is, however, uncertain whether exocytosis and endocytosis are tightly coupled, such that secretory vesicles fuse only transiently with the plasma membrane before being internalized (the 'kiss-and-run' mechanism), or whether endocytosis occurs by an independent process following complete incorporation of the secretory vesicle into the plasma membrane. Here we investigate the fate of single secretory vesicles after fusion with the plasma membrane by measuring capacitance changes and transmitter release in rat chromaffin cells using the cell-attached patch-amperometry technique. We show that raised concentrations of extracellular calcium ions shift the preferred mode of exocytosis to the kiss-and-run mechanism in a calcium-concentration-dependent manner. We propose that, during secretion of neurotransmitters at synapses, the mode of exocytosis is modulated by calcium to attain optimal conditions for coupled exocytosis and endocytosis according to synaptic activity.