Kinetic analysis of the triggered exocytosis/endocytosis secretory cycle in cultured bovine adrenal medullary cells

Cultured bovine adrenal medullary cells are an excellent preparation for quantitative analysis of the secretory exocytosis/endocytosis cycle. In this paper we examine the kinetics of endocytosis after stimulation of secretion. Membrane retrieval was monitored by uptake of the fluid phase marker horseradish peroxidase. Horseradish peroxidase was found to be suitable because it can be washed off completely, assayed quantitatively, and its uptake increases linearly with concentration. If this marker is present during stimulation, the rate of uptake is initially slower than catecholamine secretion but faster at a later time, suggesting that the formation of endocytotic vesicles follows exocytosis. To monitor the time-dependent concentration of secretory vesicle-plasma membrane fusion product (omega-profiles), secretion was halted at various time intervals after stimulation and the excess membrane allowed to transform into endocytotic vesicles in the presence of horseradish peroxidase. By adding horseradish peroxidase at various times after inhibition of secretion, the time course of membrane retrieval could be measured directly. All our results are consistent with a two-step kinetic model in which exocytosis and membrane retrieval are consecutive events. The estimated volumes of the compartments involved are roughly equal. The rate of endocytosis is strongly temperature-dependent but unaffected by extracellular calcium in the range of 10(-8)-2.5 X 10(-3) M, suggesting that calcium is not required at the site of endocytotic membrane fusion. Membrane retrieval is also unaffected by Lanthanum (1 mM) but is slowed by hypertonic media.     

Fluid-Phase Markers in the Basolateral Endocytic Pathway Accumulate in Response to the Actin Assembly-promoting Drug Jasplakinolide

To investigate the role of filamentous actin in the endocytic pathway, we used the cell-permeant drug Jasplakinolide (JAS) to polymerize actin in intact polarized Madin–Darby canine kidney (MDCK) cells. The uptake and accumulation of the fluid-phase markers fluorescein isothiocyanate (FITC)-dextran and horseradish peroxidase (HRP) were followed in JAS-treated or untreated cells with confocal fluorescence microscopy, biochemical assays, and electron microscopy. Pretreatment with JAS increased the uptake and accumulation of fluid-phase markers in MDCK cells. JAS increased endocytosis in a polarized manner, with a marked effect on fluid-phase uptake from the basolateral surface but not from the apical surface of polarized MDCK cells. The early uptake of FITC-dextran and HRP was increased more than twofold in JAS-treated cells. At later times, FITC-dextran and HRP accumulated in clustered endosomes in the basal and middle regions of JAS-treated cells. The large accumulated endosomes were similar to late endosomes but they were not colabeled for other late endosome markers, such as rab7 or mannose-6-phosphate receptor. JAS altered transport in the endocytic pathway at a later stage than the microtubule-dependent step affected by nocodazole. JAS also had a notable effect on cell morphology, inducing membrane bunching at the apical pole of MDCK cells. Although other studies have implicated actin in endocytosis at the apical cell surface, our results provide novel evidence that filamentous actin is also involved in the endocytosis of fluid-phase markers from the basolateral membrane of polarized cells.     

Delivery of lectin-labeled membrane to the trans-Golgi network and secretory granules in cultured atrial myocytes

To examine whether and how internalized plasma membrane components are routed to the compartment of the biosynthetic-exocytic pathway in cultured atrial myocytes, the plasma membrane labeled with wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) was traced electron microscopically by cytochemical detection of HRP. The WGA-HRP label was internalized via a coated pit-small vesicle pathway and reached vacuoles and endosomes by 3 min. Labeled endosomes comprised vacuoles and tubular elements containing reaction product. By 15 min, similar tubular structures containing reaction product accumulated in the area of the trans-Golgi network (TGN). The labeled TGN consisted of interconnected tubular elements, which often connected to atrial granules containing reaction product. In contrast, neither native HRP nor Lucifer Yellow reached Golgi elements or atrial granules. These results suggest that a proportion of the plasma membrane labeled with WGA-HRP is delivered to endosomes, from which tubules might bud off to transfer the tracer molecules to the TGN, where the lectin conjugate and associated membranes are packaged into atrial granules.     

The cellular uptake of horseradish peroxidase and its poly(lysine) conjugate by cultured fibroblasts is qualitatively similar despite a 900-fold difference in rate

When horseradish peroxidase (HRP) is conjugated to poly(L-lysine) of molecular weight (MW) 13,000, its transport into cultured L929 fibroblasts in 1 hour at 37 degrees C is increased 918-fold. The kinetics of uptake are linear with time and concentration, reflecting a process of nonreceptor-mediated adsorptive endocytosis. Neither HRP-poly(Lys) conjugate nor free poly(Lys) of any size cause any increase in fluid phase endocytosis. All evidence indicates that the covalently bound poly(Lys) increases the binding of HRP to the cell surface and that this adequately accounts for an increased internalization occurring at a steady rate. In the absence of Ca++, both surface binding and uptake of the conjugate, but not of free HRP, are decreased. Cytochalasin B does not significantly inhibit the transport of either form of HRP. The half-lives of HRP and HRP-poly(Lys) are 7.6 and 5.6 hours, respectively, when measured over a period of 12 hours. Electron microscopic analysis of cells that have ingested comparable amounts of HRP shows that the intracellular localization of free and conjugated HRP are comparable and that both are found inside the same array of structures. Thus HRP, which binds very poorly to the cell surface and is considered a fluid-phase marker for the "contents" of pinocytotic vesicles, and HRP-poly(Lys), which binds very strongly to the cell surface and is considered a membrane marker for adsorptive endocytosis, are taken up along the same endocytotic pathway. Moreover, despite the fact that neither markers are transported by receptor-mediated endocytosis, both are seen in structures that were described as receptosomes. It appears, therefore, that the pathways utilized in receptor-mediated transport are available to all other forms of pinocytosis.     

Two threshold values of low pH block endocytosis at different stages.

The influence of low extracellular pH on endocytosis was studied in baby hamster kidney cells. When the extracellular medium was adjusted to pH 5.7, the intracellular pH decreased within 2 min to pH 6.2 and the endocytosis of horseradish peroxidase (HRP) in the fluid phase dropped to an undetectable level. With an external pH of 6.3, the internal pH dropped to pH 6.8 and HRP was internalized at a normal rate for 5 min but accumulation during longer incubation times did not occur. Morphologically, HRP was visualized in the lumen of a subpopulation of tubular and vesicular endosomes. These observations were confirmed by subcellular fractionation studies using free flow electrophoresis. Low extracellular pH also had an effect on the endocytosis of the membrane-spanning glycoprotein G of vesicular stomatitis virus which was implanted into the plasma membrane. The internalization of G-protein was quantitated by a surface fluoroimmunoassay. The endocytosis of G-protein was not affected when the external pH was dropped to 6.3, but was reduced at an external pH of 5.7. The intracellular ATP was not depleted and the reduction of endocytosis was reversible upon return to physiological pH. Clathrin coated pits were detected by electron microscopy at the plasma membrane of the low-pH-treated cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of cholesterol and lipoproteins on endocytosis by a monocyte-like cell line

The human monocyte/macrophage-like cell line U937 is a cholesterol auxotroph. Incubation of these cells in the growth medium in which delipidated fetal calf serum has been substituted for fetal calf serum depletes cellular cholesterol and inhibits growth. The cholesterol requirement of these cells for growth can be satisfied by human low-density lipoprotein (LDL), and very-low-density lipoprotein (VLDL), but not by high-density lipoprotein (HDL). U937 cells can bind and degrade LDL via a high-affinity site and this recognition is altered by acetylation of LDL. This indicates that these cells express relatively high LDL receptor activity and low levels of the acetyl-LDL receptor. The cells were used to study the role of cholesterol in lectin-mediated and fluid-phase endocytosis. Growth of the cells in the medium containing delipidated fetal calf serum results in impairment of both concanavalin A-mediated endocytosis of horseradish peroxidase and concanavalin A-independent endocytosis of Lucifer Yellow. Supplementation of the medium with cholesterol prevents cellular cholesterol depletion, supports growth and stimulates Lucifer Yellow endocytosis but fails to restore horseradish peroxidase endocytosis. However, if the cells are incubated in the presence of no less than 40 μg LDL protein/ml to maintain normal cell cholesterol levels, concanavalin A-mediated endocytosis of horseradish peroxidase is activated. The effect of LDL is specific since neither VLDL nor HDL₃ at the same protein concentration activates horseradish peroxidase uptake by the cells. Furthermore, the activation of endocytosis by LDL is not inhibited by the inclusion of heparin or acetylation of the LDL indicating that binding of LDL to the LDL receptor is not required for these effects. The mediation of activation of horseradish peroxidase endocytosis by the lectin is presumed to involve binding of LDL to concanavalin A associated with the cell surface which in turn stimulates horseradish peroxidase binding and uptake by adsorptive endocytosis. The rate of fluid endocytosis and endosome formation seems to depend on cellular cholesterol content presumably because cholesterol is involved in maintaining the appropriate plasma membrane structure and fluidity.     

Inhibition of pinocytosis in rat embryo fibroblasts treated with monensin

Rat embryo fibroblasts cultured in the presence of monensin exhibited an inhibited uptake of horseradish peroxidase. The inhibition was detected after 3 h, after which time the cells became increasingly vacuolated; the concentration of monensin required to inhibit pinocytosis (0.4 microM for half-maximum inhibition at 18 h) was similar to that found by others to inhibit secretion. Both the exchange of 5'-nucleotidase between the membranes of cytoplasmic organelles and the cell surface and the internalization of anti-5'-nucleotidase bound to the cell surface were inhibited by approximately 90% in monensin- treated cells. The effects of monensin were reversible: cells cultured first with monensin, and then in fresh medium, exhibited control levels of horseradish peroxidase uptake, exchange of 5'-nucleotidase, and internalization of anti-5'-nucleotidase bound to the cell surface. After monensin treatment, the median density of both galactosyl transferase and 5'-nucleotidase increased from 1.128 to 1.148, and the median density of both N-acetyl-beta-glucosaminidase and horseradish peroxidase taken up by endocytosis decreased from 1.194 to 1.160. The results indicate that monensin is a reversible inhibitor of pinocytosis and, presumably, therefore, of membrane recycling. They suggest that the inhibition of membrane recycling occurs at a step other than the fusion of pinocytic vesicles with lysosomes and is perhaps a consequence of an effect of the ionophore on the Golgi complex.     

Fusion of sequentially internalized vesicles in alveolar macrophages

Previously we reported that internalized ligand-receptor complexes are transported within the alveolar macrophage at a rate that is independent of the ligand and/or receptor but is dependent on the endocytic apparatus (Ward, D. M., R. S. Ajioka, and J. Kaplan. 1989. J. Biol. Chem. 264:8164-8170). To probe the mechanism of intracellular vesicle transport, we examined the ability of vesicles internalized at different times to fuse. The mixing of ligands internalized at different times was studied using the 3,3'-diaminobenzidine/horseradish peroxidase density shift technique. The ability of internalized vesicles to fuse was dependent upon their location in the endocytic pathway. When ligands were administered as tandem pulses a significant amount of mixing (20-40%) of vesicular contents was observed. The pattern of mixing was independent of the ligands employed (transferrin, mannosylated BSA, or alpha macroglobulin), the order of ligand addition, and temperature (37 degrees C or 28 degrees C). Fusion was restricted to a brief period immediately after internalization. The amount of fusion in early endosomes did not increase when cells, given tandem pulses, were chased such that the ligands further traversed the early endocytic pathway. Little fusion, also, was seen when a chase was interposed between the two ligand pulses. The temporal segregation of vesicle contents seen in early endosomes was lost within late endosomes. Extensive mixing of vesicle contents was observed in the later portion of the endocytic pathway. This portion of the pathway is defined by the absence of internalized transferrin and is composed of ligands en route to lysosomes. Incubation of cells in iso-osmotic medium in which Na+ was replaced by K+ inhibited movement of internalized ligands to the lysosome, resulting in ligand accumulation within the late endocytic pathway. The accumulation of ligand was correlated with extensive mixing of sequentially internalized ligands. Although significant amounts of ligand degradation were observed, this compartment was devoid of conventional lysosomal markers such as acid glycosidases. These results indicate changing patterns of vesicle fusion within the endocytic pathway, with a complete loss of temporal ligand segregation in a prelysosomal compartment.     

Imaging single retrovirus entry through alternative receptor isoforms and intermediates of virus-endosome fusion

A large group of viruses rely on low pH to activate their fusion proteins that merge the viral envelope with an endosomal membrane, releasing the viral nucleocapsid. A critical barrier to understanding these events has been the lack of approaches to study virus-cell membrane fusion within acidic endosomes, the natural sites of virus nucleocapsid capsid entry into the cytosol. Here we have investigated these events using the highly tractable subgroup A avian sarcoma and leukosis virus envelope glycoprotein (EnvA)-TVA receptor system. Through labeling EnvA pseudotyped viruses with a pH-sensitive fluorescent marker, we imaged their entry into mildly acidic compartments. We found that cells expressing the transmembrane receptor (TVA950) internalized the virus much faster than those expressing the GPI-anchored receptor isoform (TVA800). Surprisingly, TVA800 did not accelerate virus uptake compared to cells lacking the receptor. Subsequent steps of virus entry were visualized by incorporating a small viral content marker that was released into the cytosol as a result of fusion. EnvA-dependent fusion with TVA800-expressing cells occurred shortly after endocytosis and delivery into acidic endosomes, whereas fusion of viruses internalized through TVA950 was delayed. In the latter case, a relatively stable hemifusion-like intermediate preceded the fusion pore opening. The apparent size and stability of nascent fusion pores depended on the TVA isoforms and their expression levels, with TVA950 supporting more robust pores and a higher efficiency of infection compared to TVA800. These results demonstrate that surface receptor density and the intracellular trafficking pathway used are important determinants of efficient EnvA-mediated membrane fusion, and suggest that early fusion intermediates play a critical role in establishing low pH-dependent virus entry from within acidic endosomes.     

Establishment of polarized endocytosis in differentiable intestinal HT29-18 subclones

Subclones of the HT29-18 clone, derived from a human adenocarcinoma, are able to acquire an enterocyte-like phenotype depending on the culture conditions. To investigate fluid-phase and receptor-mediated endocytosis in the polarized subclone HT29-18-C1, we established culture conditions that allowed cell growth on permeable supports. HT29-18-C1 monolayers had an electrical resistance of 43 ohms.cm2 and developed a transepithelial potential of about 2 mV. Transferrin receptors were uniformly distributed on the entire cell surface of undifferentiated HT29-18 cells but were located on the basolateral membrane of differentiated cells. Transferrin had a high affinity (Kd = 2.5 x 10(-9) M) for its receptor independent of the state of differentiation. The number of transferrin receptors and the mRNA amounts encoding them were comparable in the undifferentiated and differentiated HT29-18 cells. Transferrin was quickly internalized and recycled back to the cell surface of undifferentiated HT29-18 cells. The same phenomenon also occurred in differentiated HT29-18 cells, but the receptors were limited to the basolateral membrane. In the presence of ammonium chloride, the process was slower but remained polarized. Fluid-phase uptake was also investigated with horseradish peroxidase (HRP) in differentiated HT29-18 C1 cells. HRP that was internalized in 1 hour from a given membrane domain preferentially recycled back to the same membrane domain. No significant accumulation of the enzyme in the late endosomes and lysosomes of the differentiated HT29-18-C1 cells was observed.     

Rapid analytical and preparative isolation of functional endosomes by free flow electrophoresis

Endosomes are prelysosomal organelles that serve as an intracellular site for the sorting, distribution, and processing of receptors, ligands, fluid phase components, and membrane proteins internalized by endocytosis. Whereas the overall functions of endosomes are increasingly understood, little is known about endosome structure, composition, or biogenesis. In this paper, we describe a rapid procedure that permits analytical and preparative isolation of endosomes from a variety of tissue culture cells. The procedure relies on a combination of density gradient centrifugation and free flow electrophoresis. It yields a fraction of highly purified, functionally intact organelles. As markers for endosomes in Chinese hamster ovary cells, we used endocytosed horseradish peroxidase, FITC-conjugated dextran, and [35S]methionine-labeled Semliki Forest virus. Total postnuclear supernatants, crude microsomal pellets, or partially purified Golgi fractions were subjected to free flow electrophoresis. Endosomes and lysosomes migrated together as a single anodally deflected peak separated from most other organelles (plasma membrane, mitochondria, endoplasmic reticulum, and Golgi). The endosomes and lysosomes were then resolved by centrifugation in Percoll density gradients. Endosomes prepared in this way were enriched up to 70-fold relative to the initial homogenate and were still capable of ATP-dependent acidification. By electron microscopy, the isolated organelles were found to consist of electron lucent vacuoles and tubules, many of which could be shown to contain an endocytic tracer (e.g., horseradish peroxidase). SDS PAGE analysis of integral and peripheral membrane proteins (separated from each other by condensation in Triton X-114) revealed a unique and restricted subset of proteins when compared with lysosomes, the unshifted free flow electrophoresis peak, and total cell protein. Altogether, the purification procedure takes 5-6 h and yields amounts of endosomes (150-200 micrograms protein) sufficient for biochemical, immunological, and functional analysis.     

Sphingomyelin synthase 1-generated sphingomyelin plays an important role in transferrin trafficking and cell proliferation

Transferrin (Tf) endocytosis and recycling are essential for iron uptake and the regulation of cell proliferation. Tf and Tf receptor (TfR) complexes are internalized via clathrin-coated pits composed of a variety of proteins and lipids and pass through early endosomes to recycling endosomes. We investigated the role of sphingomyelin (SM) synthases (SMS1 and SMS2) in clathrin-dependent trafficking of Tf and cell proliferation. We employed SM-deficient lymphoma cells that lacked SMSs and that failed to proliferate in response to Tf. Transfection of SMS1, but not SMS2, enabled these cells to incorporate SM into the plasma membrane, restoring Tf-mediated proliferation. SM-deficient cells showed a significant reduction in clathrin-dependent Tf uptake compared with the parental SM-producing cells. Both SMS1 gene transfection and exogenous short-chain SM treatment increased clathrin-dependent Tf uptake in SM-deficient cells, with the Tf being subsequently sorted to Rab11-positive recycling endosomes. We observed trafficking of the internalized Tf to late/endolysosomal compartments, and this was not dependent on the clathrin pathway in SM-deficient cells. Thus, SMS1-mediated SM synthesis directs Tf-TfR to undergo clathrin-dependent endocytosis and recycling, promoting the proliferation of lymphoma cells.     

Uptake of horseradish peroxidase in spontaneous adenomas of the rat pituitary

The uptake of horseradish peroxidase was investigated by electron microscopy in 9 non-tumorous adenohypophyses and 13 spontaneous pituitary adenomas of adult female Long-Evans rats. Pituitary adenoma cells retained their ability for endocytosis and exhibited more extensive deposition of horseradish peroxidase than non-tumorous adenohypophysial cells.     

Membrane shuttle between plasma membrane, phagosomes, and pinosomes in Dictyostelium discoideum amoeboid cells

The intracellular redistribution of membrane internalized during endocytosis was studied quantitatively by a biochemical approach and by a morphometric analysis of autoradiographs in electron microscopy. Plasma membrane glycoconjugates, enzymatically labelled with radioactive galactose, were used as a membrane marker. In cells labelled at their surface either before or after the phagocytotic uptake of latex beads, subsequent endocytosis led to a redistribution of label between the plasma membrane and endosomal membranes until a steady-state was reached after about 1 h with 43% of the label on the plasma membrane. The steady-state resulted when all participating membranes carried the same surface density of label. During phagocytosis or pinocytosis the equivalent of the plasma membrane was internalized and recycled once every 20 min or 40 min, respectively. Compared to this rate a very rapid and complete mixing of membranes was observed between newly formed phagosomes and preexisting digestive vacuoles or between newly formed pinosomes and preexisting phagosomes. Due to this rapid mixing, the membranes enclosing undigestible latex beads remained fully linked to the shuttle of membrane to and from the cell surface.     

Hypertonic sucrose inhibition of endocytic transport suggests multiple early endocytic compartments

Incubation of animal cells with hypertonic sucrose and polyethylene glycol (PEG) 1,000 renders endosomes sensitive in situ to hypotonic shock (Okada and Rechsteiner, 1982). We found that: 1) in vitro endosomes were osmotically insensitive; and 2) hypertonic sucrose inhibited transport from very early endosomes to lysosomes. Endocytic vesicles were labeled by incubating Chinese hamster ovary (CHO) cells for 1-10 min at 37 degrees C with horseradish peroxidase (HRP) and/or fluorescein isothiocyanate-conjugated dextran (FITC-dextran). Cell fractions prepared in 0.25 M sucrose were hypotonically shocked by dilution with 5 mM Na phosphate buffer, pH 6.7, to a final sucrose concentration of 0.05 M. After hypotonic shock, endocytized HRP and FITC-dextran pelleted with membrane while lysosomal hydrolases did not. The HRP activity in the pellet was latent, suggesting that endosomes were resistant to osmotic shock. Uptake in the presence of hypertonic sucrose had little effect on the subsequent osmotic sensitivity of the endosomes. Uptake in the presence of hypertonic sucrose and PEG 1,000 rendered endosomes fragile to cell homogenization. Unexpectedly, the inclusion of hypertonic sucrose in the uptake and chase media inhibited the appearance of HRP in lysosomes. HRP internalized during a 10-min uptake appeared as if it were present in two physically distinct compartments, one accessible to transport inhibition by exogenous sucrose ("very early" endosomes) and the other not ("early" endosomes). After a brief uptake (1-3 min), postincubation of CHO cells in 0.25 M sucrose-containing media completely blocked transport of internalized HRP to lysosomes. This blockage could be partially relieved by cointernalization of invertase with HRP. These results suggest that transport between multiple early endosome populations is sensitive to intraorganellar osmotic conditions.     

Chinese hamster ovary cell lysosomes retain pinocytized horseradish peroxidase and in situ-radioiodinated proteins.

We used Chinese hamster ovary cells, a cell line of fibroblastic origin, to investigate whether lysosomes are an exocytic compartment. To label lysosomal contents, Chinese hamster ovary cells were incubated with the solute marker horseradish peroxidase. After an 18-h uptake period, horseradish peroxidase was found in lysosomes by cell fractionation in Percoll gradients and by electron microscope cytochemistry. Over a 24-h period, lysosomal horseradish peroxidase was quantitatively retained by Chinese hamster ovary cells and inactivated with a t 1/2 of 6 to 8 h. Lysosomes were radioiodinated in situ by soluble lactoperoxidase internalized over an 18-h uptake period. About 70% of the radioiodine incorporation was pelleted at 100,000 X g under conditions in which greater than 80% of the lysosomal marker enzyme beta-hexosaminidase was released into the supernatant. By one-dimensional electrophoresis, about 18 protein species were present in the lysosomal membrane fraction, with radioiodine incorporation being most pronounced into species of 70,000 to 75,000 daltons. After a 30-min or 2-h chase at 37 degrees C, radioiodine that was incorporated into lysosomal membranes and contents was retained in lysosomes. These observations indicate that lysosomes labeled by fluid-phase pinocytosis are a terminal component of endocytic pathways in fibroblasts.     

Triggered exocytosis and endocytosis have different requirements for calcium and nucleotides in permeabilized bovine chromaffin cells

The intracellular requirements for membrane recapture in permeabilized chromaffin cells were compared to the requirements for exocytosis from the same cells.In permeabilized bovine chromaffin cells, calcium-driven exocytosis also triggers, with a short delay, uptake of extracellular horseradish peroxidase (HRP). This internalized HRP remains compartmentalized within the cell and migrates to a low density band on a Percoll gradient which is distinct from the heavier chromaffin granules.The amount of horseradish peroxidase internalized is similar in intact and leaky cells and is approximately equivalent to the volumes secreted. Endocytosis in both preparations is blocked by botulinum toxin, operates in a collapsed membrane potential, and is inhibited by low temperature. In permeabilized cells, exocytosis and coupled endocytosis are activated by the same concentrations of Ca²⁺ and MgATP. Although secretion requires Ca²⁺ and MgATP, once exocytosis has occurred the subsequent endocytosis can proceed in the virtual absence of Ca²⁺ or MgATP, and is largely unaffected by a variety of nucleotide triphosphates (including nonhydrolyzable analogues), and cyclic nucleotides.These data suggest that endocytosis can proceed, once exocytosis has been triggered, under conditions that are quite different from those necessary to support exocytosis, and that the specific requirements for Ca²⁺ and MgATP in secretion are for the exocytotic limb of the secretory cycle rather than for the associated endocytotic pathway.We are grateful to Mr. John Gibbs for excellent technical assistance, and to the Medical Research Council (UK) for financial support.     

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.     

Characterization of the early endosome and putative endocytic carrier vesicles in vivo and with an assay of vesicle fusion in vitro

We have investigated two aspects of membrane traffic at early stages of endocytosis: membrane fusion and microtubule-dependent transport. As a marker, we have used the trans-membrane glycoprotein G of vesicular stomatitis virus implanted into the plasma membrane and then internalized for different times at 37 degrees C. The corresponding endosomal fractions were immunoisolated using the cytoplasmic domain of the G protein as antigen. These fractions were then used in an in vitro assay to quantify the efficiency of fusion between endosomal vesicles. To identify the vesicular partners of the fusion, these in vitro studies were combined with in vivo biochemical and morphological experiments. Internalized molecules were delivered to early endosomal elements, which corresponded to a network of tubular and tubulovesicular structures. Rapid recycling back to the plasma membrane and routing to late stages of the pathway occurred from these early endosomal elements. These elements exhibited a high and specific fusion activity with each other in vitro, suggesting that individual elements of the early endosomal compartment interact with each other in vivo. After their appearance in the early endosome, the molecules destined to be degraded were observed at the next stage of the pathway in distinct spherical vesicles (0.5 micron diam) and then in late endosomes and lysosomes. When the microtubules were depolymerized with nocodazole, endocytosis proceeded as in control cells. However, internalized molecules remained in the spherical vesicles and did not appear in late endosomes or lysosomes. These spherical vesicles had relatively little fusion activity with each other or with early endosomal elements in vitro. Our observations suggest that the spherical vesicles mediate transport between the early endosome and late endosomes and that this process requires intact microtubules.