Unitary exocytotic and endocytotic events in guard-cell protoplasts during osmotically driven volume changes

Osmotically driven swelling and shrinking of guard-cell protoplasts (GCPs) requires adjustment of surface area which is achieved by addition and removal of plasma membrane material. To investigate the mechanism for adaptation of surface area we have used patch-clamp capacitance measurements. The recorded membrane capacitance (C(m)) trace of swelling and shrinking GCPs occasionally revealed discrete upward and downward deflecting capacitance steps, respectively, with a median value of about 2 fF. The observed capacitance steps resulted from the fusion and fission of single vesicles with a diameter of around 300 nm. We conclude that exo- and endocytosis of these vesicles accommodate for osmotically driven surface area changes in GCPs.     

Morphology of the Yeast Endocytic Pathway

Positively charged Nanogold (Nanoprobes, Stony Brook, NY) has been developed as a new marker to follow the endocytic pathway in yeast. Positively charged Nanogold binds extensively to the surface of yeast spheroplasts and is internalized in an energy-dependent manner. Internalization of gold is blocked in the end3 mutant. During a time course of incubation of yeast spheroplasts with positively charged Nanogold at 15°C, the gold was detected sequentially in small vesicles, a peripheral, vesicular/tubular compartment that we designate as an early endosome, a multivesicular body corresponding to the late endosome near the vacuole, and in the vacuole. Experiments examining endocytosis in the sec18 mutant showed an accumulation of positively charged Nanogold in approximately 30–50 nm diameter vesicles. These vesicles most likely represent the primary endocytic vesicles as no other intermediates were detected in the mutant cells, and they correspond in size to the first vesicles detected in wild-type spheroplasts at 15°C. These data lend strong support to the idea that the internalization step of endocytosis in yeast involves formation of small vesicles of uniform size from the plasma membrane.     

Insulin and alpha 2-macroglobulin-methylamine undergo endocytosis by different mechanisms in rat adipocytes: II. Comparison of intracellular events

A previous ultrastructural study showed that gold-labeled insulin (Au-I) and the non-hormonal ligand gold-labeled alpha-2-macroglobulin-methylamine (Au-alpha 2MGMA) underwent endocytosis by dissimilar cell surface structures on rat adipocytes. The present ultrastructural study compared the intracellular routes taken by these two ligands in adipocytes. Intracellular Au-alpha 2MGMA was initially found within apparent coated vesicles but Au-I was not, consistent with the previous demonstration that Au-alpha 2MGMA underwent endocytosis by coated pits whereas Au-I was internalized by uncoated micropinocytotic invaginations. Early in the endocytic pathway, the two ligands were segregated within separate small vesicles and tubulovesicles. Au-alpha 2MGMA was concentrated in a small number of these structures whereas Au-I was sparsely distributed among a relatively large number. Subsequently, the two endocytic pathways converged as the ligands intermingled within pale multivesicular bodies and lysosome-like structures. Au-I was less efficiently transferred to lysosomes than Au-alpha 2MGMA since a greater proportion of intracellular Au-I remained associated with small vesicles and tubulovesicles. This study indicates that early intracellular events in the endocytic pathways of insulin and alpha 2MGMA are distinct. These findings are discussed in light of the fundamentally dissimilar biological roles of these two molecules and the possible involvement of the endocytic pathway in the insulin signaling mechanism.     

Receptor-mediated endocytosis of transferrin and ferritin by guinea-pig reticulocytes. Uptake by a common endocytic pathway

Earlier studies have shown that transferrin binds to specific receptors on the reticulocyte surface, clusters in coated pits and is then internalized via endocytic vesicles. Guinea-pig reticulocytes also have specific receptors for ferritin. In this paper ferritin and transferrin endocytosis by guinea-pig reticulocytes was studied by electron microscopy using the natural electron density of ferritin and colloidal gold-transferrin (AuTf). At 4 degrees C both ligands bound to the cell surface. At 37 degrees C progressive uptake occurred by endocytosis. AuTf and ferritin clustered in the same coated pits and small intracellular vesicles. After 60 min incubations the ligands colocalized to large multivesicular endosomes (MVE), still membrane-bound. MVE subsequently fused with the plasma membrane and released AuTf, ferritin and inclusions by exocytosis. All endocytic structures labelled with AuTf contained ferritin, but 23 to 35% of ferritin-labelled endocytic structures contained no AuTf. These data suggest that ferritin and transferrin are internalized through the same pathway involving receptors, coated pits and vesicles, but that these proteins are recycled only partly in common.     

Dynamics of clathrin and adaptor proteins during endocytosis

The endocytic adaptor complex AP-2 colocalizes with the majority of clathrin-positive spots at the cell surface. However, we previously observed that AP-2 is excluded from internalizing clathrin-coated vesicles (CCVs). The present studies quantitatively demonstrate that AP-2 disengages from sites of endocytosis seconds before internalization of the nascent CCV. In contrast, epsin, an alternate adaptor for clathrin at the plasma membrane, disappeared, along with clathrin. This suggests that epsin remains an integral part of the CCV throughout endocytosis. Clathrin spots at the cell surface represent a heterogeneous population: a majority (70%) of the spots disappeared with a time course of 4 min, whereas a minority (22%) remained static for 30 min. The static clathrin spots undergo constant subunit exchange, suggesting that although they are static structures, these spots comprise functional clathrin molecules, rather than dead-end aggregates. These results support a model where AP-2 serves a cargo-sorting function before endocytosis, whereas alternate adaptors, such as epsin, actually link cargo to the clathrin coat surrounding nascent endocytic vesicles. These data also support a role for static clathrin, providing a nucleation site for endocytosis. adaptor complex; epsin; total internal reflection fluorescence microscopy     

Plasma membrane-derived vesicles containing receptor-ligand complexes are fusogenic with early endosomes in a cell-free system

Receptor-mediated endocytosis involves the transport of receptor-ligand complexes from the cell surface to an intracellular endocytic compartment. This study shows that plasma membrane-derived vesicles containing receptor-bound ligands (e.g. aggregated anti-dinitrophenol (DNP) IgG bound to Fc receptors) fuse with early endosomes containing DNP-beta-glucuronidase in a cell-free system. Plasma membrane vesicles were generated by homogenization of cells that had been allowed to bind ligands at 4 degrees C. Fusion between vesicles containing the two probes was assessed by (i) the formation of anti-DNP IgG-DNP-beta-glucuronidase complexes and (ii) the colocalization within closed vesicles of two different sizes of colloidal gold coated with ligands. Fusion required ATP, cytosol, and KCl. The requirements were similar to those described for endosome-endosome fusion in in vitro systems. Mild trypsinization of vesicles prior to their addition to the assay inhibited fusion. When DNP-beta-glucuronidase was chased into more mature endocytic compartments, fusion was not observed. The results indicate that cell surface regions involved in receptor-mediated endocytosis are capable of fusing to early endosomes. This fusion event may constitute the first step in the transport of ligands to an intracellular endocytic compartment.     

The preendosomal compartment comprises distinct coated and noncoated endocytic vesicle populations

The transfer of molecules from the cell surface to the early endosomes is mediated by preendosomal vesicles. These vesicles, which have pinched off completely from the plasma membrane but not yet fused with endosomes, form the earliest compartment along the endocytic route. Using a new assay to distinguish between free and cell surface connected vesicle profiles, we have characterized the preedosomal compartment ultrastructurally. Our basic experimental setup was labeling of the entire cell surface at 4 degrees C with Con A-gold, warming of the cells to 37 degrees C to allow endocytosis, followed by replacing incubation medium with fixative, all within either 30 or 60 s. Then the fixed cells were incubated with anti-Con A-HRP to distinguish truly free (gold labeled) endocytic vesicles from surface-connected structures. Finally, analysis of thin (20-30 nm) serial sections and quantification of vesicle diameters were carried out. Based on this approach it is shown that the preendosomal compartment comprises both clathrin-coated and non-coated endocytic vesicles with approximately the same frequency but with distinct diameter distributions, the average noncoated vesicle being smaller (95 nm) than the average coated one (110 nm). In parallel experiments, using an anti-transferrin receptor gold-conjugate as a specific marker for clathrin-dependent endocytosis it is also shown that uncoating of coated vesicles plays only a minor role for the total frequency of noncoated vesicles. Furthermore, after perturbation of clathrin-dependent endocytosis by potassium depletion where uptake of transferrin is blocked, noncoated endocytic vesicles with Con A-gold, but not coated vesicles, exist already after 30 and 60 s. Finally, it is shown that the existence of small, free vesicles in the short-time experiments cannot be ascribed to recycling from the early endosomes.     

Identification of a cold-sensitive step in the mechanism of modeccin action

Modeccin is a toxic lectin that arrests protein synthesis in mammalian cells by catalytically inactivating 60 S ribosomes. To interact with 60 S ribosomes, the catalytic subunit of modeccin must pass through a membrane and enter the cytosol. Two known steps in the mechanism of modeccin action are the receptor-mediated internalization of the toxin into vesicles and a second step that requires a low pH within the vesicles. We report here another step required for modeccin to arrest protein synthesis, identified because this step was blocked at 15 degrees C. Modeccin traveling from cell surface receptors to the cytosol at 37 degrees C passed the low pH step within vesicles in a minimum time of 15 min after endocytosis and reached the cold-sensitive step 15 min later. There was no effect on protein synthesis until about 45 min after modeccin had passed the cold-sensitive step, suggesting that the toxin was still within vesicles at the time of the cold-sensitive event. The low temperature at which modeccin failed to reach the cytosol correlated with an apparent low temperature block in the transfer of endocytosed modeccin to lysosomes. The possibility is discussed that modeccin does not penetrate to the cytosol directly from endocytic vesicles.     

Programmed Endocytosis During Epiboly of Fundulus heteroclitus

A major question in the analysis of teleost epiboly is the fateof the yolk cytoplasmic layer. It diminishes during epibolyand eventually disappears at the completion of epiboly. Thispaper is concerned with the fate of the surface of the yolkcytoplasmic layer during epiboly. When gastrulae during epibolyare bathed in lucifer yellow (CH) and then observed with fluorescentmicroscopy or bathed in ferritin and then fixed and observedwith TEM, a thin circumferential ring of endocytic vesiclesis observed, confined to the external yolk syncytial layer justperipheral to the advancing margin of the blastoderm. Even thoughthe entire egg is immersed in the marker, endocytosis is confinedto this limited region. More precisely, this endocytosis occursonly within the region of the external yolk syncytial layer,where the surface is most folded. The endocytic vesicles thusformed move downward and settle on the surface of the membraneseparating the yolk from the cytoplasm in the yolk syncytiallayer. They do not join the surface of the internal yolk syncytiallayer; hence they do not contribute to its expansion. Priorto the onset of epiboly there is no such endocytosis at thesurface of the egg. Since this endocytosis occurs only duringepiboly and only at the surface of the external yolk syncytiallayer just peripheral to the advancing margin of the blastoderm,and in the absence of large molecules in the medium, we concludethat it is programmed. We, therefore, present this as a caseof programmed internalization of cell surface serving as themorphogenetic mechanism responsible for the disappearance ofthe surface of the yolk cytoplasmic layer during gastrulationof the teleost Fundulus heteroclitus     

Study on the origin of apical tubules in ileal absorptive cells of suckling rats using concanavalin-A as a membrane-bound tracer

Summary The ileal absorptive cells of suckling rats exhibit high levels of endocytic activity being engaged in nonselective uptake of macromolecules from the intestinal lumen. The apical cytoplasm usually contains an extensive network of small, membrane-limited tubules (apical tubules: AT), in addition to newly formed endocytic vesicles and large endocytic vacuoles. To determine whether the AT are directly involved in the endocytic process by carrying the tracer into the cell, we have analysed movements of the apical cell membrane of the ileal absorptive cells by using a membrane-bound tracer (horseradish peroxidase-labelled cancanavalin-A: Con-A HRP). The ileal absorptive cells were exposed in vitro to Con-A HRP for 10 min at 4° C, incubated for different times in Con-A free medium at 37° C, and prepared for electron microscopy. After 1 min incubation at 37° C, invaginations of the apical cell membrane, including coated pits, and endocytic vesicles were labelled with HRP-reaction product, whereas the AT and large endocytic vacuoles were negative. After 2.5 min, almost all the large endocytic vacuoles were labelled with reaction product, which was seen in their vacuolar lumen and along the luminal surface of their limiting membrane. A few AT with reaction product were seen in the apical cytoplasm; they were in frequent connection with the reaction-positive large endocytic vacuoles. With increasing incubation time, the number of the labelled AT increased. Thus, after 15 min at 37° C, the apical cytoplasm was fully occupied by the reaction-positive AT. The ends of these AT were often continuous with small spherical coated vesicles. No reaction product was detected in the Golgi complex at any time after incubation. These observations indicate that the AT located in the apical cytoplasm probably originate by budding off from the large endocytic vacuoles, rather than being involved in the process of endocytosis.     

Two independent forms of endocytosis maintain embryonic cell surface homeostasis during early development

Eukaryotic cells have multiple forms of endocytosis which maintain cell surface homeostasis. One explanation for this apparent redundancy is to allow independent retrieval of surface membranes derived from different types of vesicles. Consistent with this hypothesis we find that sea urchin eggs have at least two types of compensatory endocytosis. One is associated with retrieving cortical vesicle membranes, and formed large endosomes by a mechanism that was inhibited by agatoxin, cadmium, staurosporine and FK506. The second type is thought to compensate for constitutive exocytosis, and formed small endosomes using a mechanism that was insensitive to the above mentioned reagents, but was inhibited by phenylarsine oxide (PAO), and by microinjection of mRNA encoding Src kinase. Both mechanisms could act concurrently, and account for all of the endocytosis occurring during early development. Inhibition of either form did not trigger compensation by the other form, and phorbol ester treatment rescued the endocytotic activity blocked by agatoxin, but not the retrieval blocked by PAO.     

Clathrin‐Mediated Endocytosis at the Synaptic Terminal: Bridging the Gap Between Physiology and Molecules

It has long been known that the maintenance of fast communication between neurons requires that presynaptic terminals recycle the small vesicles from which neurotransmitter is released. But the mechanisms that retrieve vesicles from the cell surface are still not understood. Although we have a wealth of information about the molecular details of endocytosis in non‐neuronal cells, it is clear that endocytosis at the synapse is faster and regulated in distinct ways. A satisfying understanding of these processes will require molecular events to be manipulated while observing endocytosis in living synapses. Here, we review recent work that seeks to bridge the gap between physiology and molecules to unravel the endocytic machinery operating at the synaptic terminal.     

Ultrastructural analysis of asialoglycoprotein receptor mediated endocytosis in cultured newborn hepatocytes

We examined the receptor-mediated endocytosis of asialoglycoproteins in thick sections of cultured hepatocytes of newborn rats by high voltage electron microscope. The organelles involved in endocytosis are revealed ultrastructurally using colloidal gold particles coupled to lactosylated bovine serum albumin. Keeping the cells at 4 degrees C the marker binds to the cell surface showing microvilli, and is not internalized. Increasing the temperature to 37 degrees C, we observed that within 5-15 min. the marker enters the intracellular endocytic organelles close to the cell surface. After 60 min. the marker is found in the larger and deeper endocytic organelles and in large lisosome-like vesicles. We find that the process of endocytosis in newborn cultured hepatocytes is similar to that found in cultured cells of adult rats, but the process of internalization is slower.     

Azithromycin,a lysosomotropic antibiotic,has distinct effects on fluid-phase and receptor-mediated endocytosis,but does not impair phagocytosis in J774 macrophages

Pretreatment of J774 mouse macrophages by the dicationic macrolide antibiotic, azithromycin (AZ), selectively inhibited fluid-phase endocytosis of horseradish peroxidase and lucifer yellow, but not phagocytosis of latex beads. AZ delayed sequestration of receptor-bound transferrin and peroxidase-anti-peroxidase immune complexes into cell-surface endocytic pits and vesicles, but did not slow down the subsequent rate of receptor-mediated endocytosis. AZ down-regulated cell surface transferrin receptors, but not Fc gamma receptors, by causing a major delay in the accessibility of internalized transferrin receptors to the recycling route, without slowing down subsequent efflux, resulting in redistribution of the surface pool to an intracellular pool. Acidotropic accumulation of AZ was associated with an extensive vacuolation of late endosomes/lysosomes, and these compartments became inaccessible to horseradish peroxidase and immune complexes, but not to latex beads. The inhibitory profile of AZ cannot be solely accounted for by vacuolation and interference with acidification. AZ may help in dissecting various steps of the endocytic apparatus such as lateral mobility of receptors at the plasma membrane, formation of clathrin-independent endocytic vesicles, orientation of transferrin receptors into the recycling route, and fusogenicity with lysosomes.     

Flow and shuttle of plasma membrane during endocytosis

A striking feature of endocytosis is the large amount of surface membrane that is brought into the cells through the formation of endocytic vesicles. Little is known about the fate of this membrane material. It is implausible that it would be destroyed in lysosomes, as the rate of turnover of the constituents of plasma membrane is much too low with respect to the rate of endocytosis in all cells studied so far. Conversely, plasma membrane fragments, internalized by endocytosis cannot merely be incorporated in lysosomes, as these organelles have been shown to maintain their size, despite continuous and active endocytosis. We present evidence that plasma membrane antigens, detected by means of specific antibodies, are internalized during endocytosis and reach lysosomes. They are thereafter returned back to cell surface. These results indicate the existence of a shuttle of membrane elements between the cell surface and lysosomes.     

Methods for Cell-attached Capacitance Measurements in Mouse Adrenal Chromaffin Cell

Neuronal transmission is an integral part of cellular communication within the brain. Depolarization of the presynaptic membrane leads to vesicle fusion known as exocytosis that mediates synaptic transmission. Subsequent retrieval of synaptic vesicles is necessary to generate new neurotransmitter-filled vesicles in a process identified as endocytosis. During exocytosis, fusing vesicle membranes will result in an increase in surface area and subsequent endocytosis results in a decrease in the surface area. Here, our lab demonstrates a basic introduction to cell-attached capacitance recordings of single endocytic events in the mouse adrenal chromaffin cell. This type of electrical recording is useful for high-resolution recordings of exocytosis and endocytosis at the single vesicle level. While this technique can detect both vesicle exocytosis and endocytosis, the focus of our lab is vesicle endocytosis. Moreover, this technique allows us to analyze the kinetics of single endocytic events. Here the methods for mouse adrenal gland tissue dissection, chromaffin cell culture, basic cell-attached techniques, and subsequent examples of individual traces measuring singular endocytic event are described.     

Binding of filamin to the C-terminal tail of the calcitonin receptor controls recycling

Many G protein-coupled receptors undergo endocytosis, but the mechanisms involved in endocytic sorting and recycling remain to be fully elucidated. We found that the G protein-coupled calcitonin receptor (CTR) undergoes tonic internalization and accumulates within the cell. Using a fluorescence loss in photobleaching assay, we classified these vesicles functionally as recycling vesicles. In a two-hybrid screening, we found that the actin-binding protein filamin interacted with the C-terminal tail of the CTR. The degradation of the receptor was profoundly increased in the absence of filamin or the CTR-filamin interaction. The absence of filamin was also associated with a marked decrease in recycling of the receptor from the endosomes to the cell surface. In contrast, calcitonin-induced inhibition of spontaneous filamin proteolysis was associated with increased recycling of the receptor to the cell surface and decreased degradation of the CTR, suggesting an important role for filamin in the endocytic sorting and recycling of the internalized CTR.     

Annexin VI stimulates endocytosis and is involved in the trafficking of low density lipoprotein to the prelysosomal compartment

Annexins are calcium-binding proteins with a wide distribution in most polarized and nonpolarized cells that participate in a variety of membrane-membrane interactions. At the cell surface, annexin VI is thought to remodel the spectrin cytoskeleton to facilitate budding of coated pits. However, annexin VI is also found in late endocytic compartments in a number of cell types, indicating an additional important role at later stages of the endocytic pathway. Therefore overexpression of annexin VI in Chinese hamster ovary cells was used to investigate its possible role in endocytosis and intracellular trafficking of low density lipoprotein (LDL) and transferrin. While overexpression of annexin VI alone did not alter endocytosis and degradation of LDL, coexpression of annexin VI and LDL receptor resulted in an increase in LDL uptake with a concomitant increase of its degradation. Whereas annexin VI showed a wide intracellular distribution in resting Chinese hamster ovary cells, it was mainly found in the endocytic compartment and remained associated with LDL-containing vesicles even at later stages of the endocytic pathway. Thus, data presented in this study suggest that after stimulating endocytosis at the cell surface, annexin VI remains bound to endocytic vesicles to regulate entry of ligands into the prelysosomal compartment.     

Acidification of endocytic compartments and the intracellular pathways of ligands and receptors

Several hormones, serum proteins, toxins, and viruses are brought into the cell by receptor-mediated endocytosis. Initially, many of these molecules and particles are internalized into a common endocytic compartment via the clathrin-coated pit pathway. Subsequently, the ligands and receptors are routed to several destinations, including lysosomes, the cytosol, or the plasma membrane. We have examined the mechanism by which sorting of internalized molecules occurs. A key step in the process is the rapid acidification of endocytic vesicles to a pH of 5.0-5.5 This acidification allows dissociation of several ligands from their receptors, the release of iron from transferrin, and the penetration of diphtheria toxin and some viral nucleocapsids into the cytoplasm. Transferrin, a ligand that cycles through the cell with its receptor, has been used as a marker for the recycling receptor pathway. We have found that in Chinese hamster ovary (CHO) cells transferrin is rapidly segregated from other ligands and is routed to a complex of small vesicles and/or tubules near the Golgi apparatus. The pH of the transferrin-containing compartment is approximately 6.4, indicating that it is not in continuity with the more acidic endocytic vesicles which contain ligands destined to be degraded in lysosomes.     

Endocytosis and vesicle trafficking during tip growth of root hairs

Summary. The directional elongation of root hairs, “tip growth”, depends on the coordinated and highly regulated trafficking of vesicles which fill the tip cytoplasm and are active in secretion of cell wall material. So far, little is known about the dynamics of endocytosis in living root hairs. We analyzed the motile behaviour of vesicles in the apical region of living root hairs of Arabidopsis thaliana and of Triticum aestivum by live cell microscopy. For direct observation of endocytosis and of the fate of endocytic vesicles, we used the fluorescent endocytosis marker dyes FM 1-43 and FM 4-64. Rapid endocytosis was detected mainly in the tip, where it caused a bright fluorescence of the apical cytoplasm. The internalized membranes proceeded through highly dynamic putative early endosomes in the clear zone to larger endosomal compartments in the subapical region that are excluded from the clear zone. The internalized cargo ended up in the dynamic vacuole by fusion of large endosomal compartments with the tonoplast. Before export to these lytic compartments, putative early endosomes remained in the apical zone, where they most probably recycled to the plasma membrane and back into the cytoplasm for more than 30 min. Endoplasmic reticulum was not involved in trafficking pathways of endosomes. Actin cytoskeleton was needed for the endocytosis itself, as well as for further membrane trafficking. The actin-depolymerizing drug latrunculin B modified the dynamic properties of vesicles and endosomes; they became immobilized and aggregated in the tip. Treatment with brefeldin A inhibited membrane trafficking and caused the disappearance of FM-containing vesicles and putative early endosomes from the clear zone; labelled structures accumulated in motile brefeldin A-induced compartments. These large endocytic compartments redispersed upon removal of the drug. Our results hence prove that endocytosis occurs in growing root hairs. We show the localization of endocytosis in the tip and indicate specific endomembrane compartments and their recycling. Correspondence and reprints: Institute of Botany, Slovak Academy of Sciences, Dubravska cesta 14, 845 23 Bratislava, Slovak Republic.