Effect of phenylarsine oxide on fluid phase endocytosis: further evidence for activation of the glucose transporter

We have shown previously that insulin stimulates fluid phase endocytosis in 3T3-L1 adipocytes (Gibbs et al., 1986). Using [14C]sucrose as an endocytotic marker, we show here that phenylarsine oxide, a trivalent arsenical which binds neighboring dithiols, blocked not only insulin-stimulated fluid phase endocytosis, but basal endocytosis as well. The Ki for this process was 6 microM in the presence or absence of insulin and the time required for inhibition was less than 2.5 min, the limit of detection in our assay system. These results can be compared with the inhibitory effect of phenylarsine oxide on insulin-stimulated glucose transport. Although the Ki for insulin-stimulated transport (7 microM) was similar to that for inhibition of endocytosis, basal glucose transport was not affected by the inhibitor. Further, when cells were prestimulated with insulin causing maximal stimulation of the glucose transport rate, phenylarsine oxide induced a time-dependent reduction to the basal rate (t 1/2 of 10 min), despite the fact that endocytosis was blocked immediately. This observation suggests that if the transporter is recycled by an exocytotic/endocytotic mechanism, it is distinct from fluid-phase endocytosis/exocytosis, which is a vesicle-mediated process, and provides further evidence that the transporter may undergo intrinsic activation/inactivation which does not require vesicle movement.     

Constitutive and transport-related endocytotic pathways in turtle bladder epithelium

Summary Proton secretion in the urinary bladder of the fresh-water turtle is mediated by a proton pump located in the apical membrane of a population of cells characteristically rich in carbonic anhydrase. Earlier studies have demonstrated that these cells exhibit apical-membrane endocytotic and exocytotic processes which are thought to be involved in the regulation of the rate of proton transport via alterations in the number of pumps within the apical membrane. In this study, we sought to characterize these processes using two different methods. Analysis of transepithelial impedance yielded estimates of membrane capacitance which could be related to membrane area, thereby allowing one to monitor net changes in apical-membrane area resulting from changes in the net rates of endo-and exocytosis. Uptake of the fluid-phase marker FITC-dextran provided a measure of net extracellular volume uptake which was related to net rates of endocytosis. Our major conclusions are summarized as follows. The bladder cells exhibit a high baseline rate of endocytosis which appears to be a constitutive process similar to pinocytosis. This process is completely inhibited when ambient temperature is reduced to 15°C. In addition, serosal application of 0.5mm acetazolamide causes a transient increase in the rate of endocytosis, concomitant with a decrease in the rate of transport. Reduction of ambient temperature to 15°C reduces the rate of acetazolamide-induced endocytosis, but does not abolish it. Addition of 1mm serosal azide not only prevents the acetazolamide-induced increase in endocytosis, but also prevents the decrease in transport caused by acetazolamide. Azide has no effect on the baseline rate of endocytosis, nor does it prevent inhibition of carbonic anhydrase by acetazolamide. The specificity of azide, coupled with the different temperature sensitivities, demonstrate that the constitutive and transport-dependent endocytotic pathways are distinct processes. The observation that azide prevents both the acetazolamide-induced increase in endocytosis and the decrease in transport strongly supports the notion that endocytosis of proton-pump-containing membrane is requisite for the inhibition of transport by acetazolamide. Finally, the results also demonstrate that acetazolamide does not inhibit proton secretion simply by inhibiting carbonic anhydrase.     

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.     

Mechanisms of alveolar protein clearance in the intact lung

Transport of protein across the alveolar epithelial barrier is a critical process in recovery from pulmonary edema and is also important in maintaining the alveolar milieu in the normal healthy lung. Various mechanisms have been proposed for clearing alveolar protein, including transport by the mucociliary escalator, intra-alveolar degradation, or phagocytosis by macrophages. However, the most likely processes are endocytosis across the alveolar epithelium, known as transcytosis, or paracellular diffusion through the epithelial barrier. This article focuses on protein transport studies that evaluate these two potential mechanisms in whole lung or animal preparations. When protein concentrations in the air spaces are low, e.g., albumin concentrations <0.5 g/100 ml, protein transport demonstrates saturation kinetics, temperature dependence indicating high energy requirements, and sensitivity to pharmacological agents that affect endocytosis. At higher concentrations, the protein clearance rate is proportional to protein concentration without signs of saturation, inversely related to protein size, and insensitive to endocytosis inhibition. Temperature dependence suggests a passive process. Based on these findings, alveolar albumin clearance occurs by receptor-mediated transcytosis at low protein concentrations but proceeds by passive paracellular mechanisms at higher concentrations. Because protein concentrations in pulmonary edema fluid are high, albumin concentrations of 5 g/100 ml or more, clearance of alveolar protein occurs by paracellular pathways in the setting of pulmonary edema. Transcytosis may be important in regulating the alveolar milieu under nonpathological circumstances. Alveolar degradation may become important in long-term protein clearance, clearance of insoluble proteins, or under pathological conditions such as immune reactions or acute lung injury. acute respiratory distress syndrome; endocytosis; diffusion; protein transport pulmonary edema     

Immunoglobulin G transport increases in an in vitro blood–brain barrier model with amyloid-β and with neuroinflammatory cytokines

Immunotherapies are a promising strategy for the treatment of neurological diseases such as Alzheimer's disease (AD), however, transport of antibodies to the brain is severely restricted by the blood–brain barrier (BBB). Furthermore, molecular transport at the BBB is altered in disease, which may affect the mechanism and quantity of therapeutic antibody transport. To better understand the transport of immunotherapies at the BBB in disease, an in vitro BBB model derived from human induced pluripotent stem cells (iPSCs) was used to investigate the endocytic uptake route of immunoglobulin G (IgG). In this model, uptake of fluorescently labeled IgGs is a saturable process. Inhibition of clathrin-mediated endocytosis, caveolar endocytosis, and macropinocytosis demonstrated that macropinocytosis is a major transport route for IgGs at the BBB. IgG uptake and transport were increased after the addition of stimuli to mimic AD (Aβ_1–40 and Aβ_1–42) and neuroinflammation (tumor necrosis factor-α and interleukin-6). Lastly, caveolar endocytosis increased in the AD model, which may be responsible for the increase in IgG uptake in disease. This study presents an iPSC-derived BBB model that responds to disease stimuli with physiologically relevant changes to molecular transport and can be used to understand fundamental questions about transport mechanisms of immunotherapies in health and neurodegenerative disease.     

Involvement of endocytosis in catabolite inactivation of the K+ and glucose transport systems in Saccharomyces cerevisiae

Abstract The possible relationship between endocytosis and catabolite inactivation of plasma membrane proteins in Saccharomyces cerevisiae has been investigated. Using mutants with an increased rate of endocytosis we have shown that there is a positive correlation between the rate of endocytosis and the rate of inactivation of the K⁺ and glucose transport systems. It is concluded that endocytosis is involved in catabolite inactivation of these two transport systems.     

Clathrin-mediated endocytosis: membrane factors pull the trigger

Clathrin-mediated endocytosis is a vesicular transport event involved in the internalization and recycling of receptors participating in signal transduction events and nutrient import as well as in the reformation of synaptic vesicles. Recent studies in vitro and in living cells have provided a number of new insights into the initial steps of clathrin-coated vesicle formation and the membrane factors involved in this process. The unexpected complexity of these interactions at the cytosol-membrane interface suggests that clathrin-coated vesicle assembly is a highly cooperative process occurring under tight regulatory control. In this review, we focus on the role of membrane proteins and lipids in the nucleation of clathrin-coated pits and provide a hypothetical model for the early steps in clathrin-mediated endocytosis.     

Receptor-mediated endocytosis: An overview of a dynamic process

The decade of the 70’s was remarkable for the insights that rapidly accumulated to provide us with an understanding of one of the fundamental processes of animal cell metabolism, namely, how mammalian cells ingest a host of extracellular substances to satisfy their various metabolic needs. It has long been appreciated that the surfaces of mammalian cells are in a continual state of flux. Surface membranes often fold inward and pinch of in a vesicular form trapping some of the contents of the extracellular material which are thus transported into the cell. This process is called endocytosis (reviewed in Silversteinet al., 1977). When extracellular fluids are taken up in this manner, the process is called fluid-phase endocytosis or pinocytosis. When solids are ingested, the process is called phagocytosis. Although quantitatively important over the long run, these modes of uptake are slow, non-specific and dependent on the concentration of the substance in the extracellular medium. In recent years it has been recognized that animal cells have developed a specialized form of this vesicular transport system to selectively retrieve and assimilate macromolecules from the extracellular milieu with high efficiency. This process is called receptor-mediated endocytosis. In this review an attempt is made to collate and correlate the evidence establishing receptor-mediated endocytosis as a dynamic process that routes cell surface receptors and ligands through multiple intracellular compartments to their ultimate destination.     

Intermediate filaments and lipoprotein cholesterol

The ability of cells to utilize cholesterol derived from lipoprotein is important in plasma membrane biosynthesis, steroidogenesis and the regulation of sterol synthesis. While the endocytosis of lipoprotein-derived cholesterol has been well characterized, the subsequent events that mediate its post-lysosomal intracellular transport are not understood. Recent studies have suggested that vimentin-type intermediate filaments may have a role in cholesterol transport. The mechanism by which vimentin filaments affect this process is not known, but future studies promise to provide new insights into both the post-lysosomal transport of cholesterol and the intracellular functions of intermediate filaments.     

Translocation of dimeric IgA through neoplastic colon cells in vitro.

We studied the translocation of dimeric IgA across epithelium, using neoplastic human colon cells in culture as a source of epithelial cells, and immunoelectronmicroscopy with peroxidase-labeled antigens and antibodies. The cells had some of the ultrastructural characteristics of normal, mature epithelial cells, i.e., polarity, desmosomal junctions, and secretory component on their basal and lateral plasma membranes. Horseradish peroxidase-labeled dimeric IgA, exposed to the cells at 0 degrees C, bound selectively to secretory component on the cell surfaces. At 37 degrees C, the bound dimeric IgA was taken into the cells by endocytosis and transported apically through the cytoplasm in vesicles. After 30 min, IgA was discharged across the apical surface. Neither colchicine (10(-4) M) nor cytochalasin B (10(-5) M) interfered with binding or endocytosis of dimeric IgA, but colchicine inhibited intracellular transport of the IgA-containing vesicles. These experiments demonstrated that dimeric IgA can be transported through living intestinal epithelial cells in vitro. The transport includes 1) specific binding of IgA dimers to secretory component on plasma membranes, 2) endocytosis of IgA in vesicles, 3) transcytoplasmic transport of the IgA-containing vesicles by a process involving microtubules, and 4) discharge of IgA at the apical surfaces.     

Studies on the internalization mechanism of cationic cell-penetrating peptides

A great deal of data has been amassed suggesting that cationic peptides are able to translocate into eucaryotic cells in a temperature-independent manner. Although such peptides are widely used to promote the intracellular delivery of bioactive molecules, the mechanism by which this cell-penetrating activity occurs still remains unclear. Here, we present an in vitro study of the cellular uptake of peptides, originally deriving from protegrin (the SynB peptide vectors), that have also been shown to enhance the transport of drugs across the blood-brain barrier. In parallel, we have examined the internalization process of two lipid-interacting peptides, SynB5 and pAntp-(43-58), the latter corresponding to the translocating segment of the Antennapedia homeodomain. We report a quantitative study of the time- and dose-dependence of internalization and demonstrate that these peptides accumulate inside vesicular structures. Furthermore, we have examined the role of endocytotic pathways in this process using a variety of metabolic and endocytosis inhibitors. We show that the internalization of these peptides is a temperature- and energy-dependent process and that endosomal transport is a key component of the mechanism. Altogether, our results suggest that SynB and pAntp-(43-58) peptides penetrate into cells by an adsorptive-mediated endocytosis process rather than temperature-independent translocation.     

Cubilin, a high-density lipoprotein receptor

The metabolism of HDL particles is a complex biological process involving various regulating factors in plasma and different cellular receptors. In addition to the well-established scavenger receptor BI-mediated selective HDL-cholesteryl ester uptake in liver and steroidogenic tissues, evidence has been provided that HDL also undergoes holoparticle endocytosis in different tissues. Recently, a novel receptor expressed in various absorptive epithelia was disclosed as a high affinity receptor for endocytosis of HDL and lipid-poor apolipoprotein AI. This receptor, designated cubilin, may play an important role in the renal clearance of filterable apolipoprotein AI/HDL and in the maternal-fetal transport of cholesterol.     

HSV‐1 Glycoproteins Are Delivered to Virus Assembly Sites Through Dynamin‐Dependent Endocytosis

Herpes simplex virus‐1 (HSV‐1) is a large enveloped DNA virus that belongs to the family of Herpesviridae. It has been recently shown that the cytoplasmic membranes that wrap the newly assembled capsids are endocytic compartments derived from the plasma membrane. Here, we show that dynamin‐dependent endocytosis plays a major role in this process. Dominant‐negative dynamin and clathrin adaptor AP180 significantly decrease virus production. Moreover, inhibitors targeting dynamin and clathrin lead to a decreased transport of glycoproteins to cytoplasmic capsids, confirming that glycoproteins are delivered to assembly sites via endocytosis. We also show that certain combinations of glycoproteins colocalize with each other and with the components of clathrin‐dependent and ‐independent endocytosis pathways. Importantly, we demonstrate that the uptake of neutralizing antibodies that bind to glycoproteins when they become exposed on the cell surface during virus particle assembly leads to the production of non‐infectious HSV‐1. Our results demonstrate that transport of viral glycoproteins to the plasma membrane prior to endocytosis is the major route by which these proteins are localized to the cytoplasmic virus assembly compartments. This highlights the importance of endocytosis as a major protein‐sorting event during HSV‐1 envelopment.      

Molecular interplay of autophagy and endocytosis in human health and diseases

Autophagy, an evolutionarily conserved process for maintaining the physio‐metabolic equilibrium of cells, shares many common effector proteins with endocytosis. For example, tethering proteins involved in fusion like Ras‐like GTPases (Rabs), soluble N‐ethylmaleimide sensitive factor attachment protein receptors (SNAREs), lysosomal‐associated membrane protein (LAMP), and endosomal sorting complex required for transport (ESCRT) have a dual role in endocytosis and autophagy, and the trafficking routes of these processes converge at lysosomes. These common effectors indicate an association between budding and fusion of membrane‐bound vesicles that may have a substantial role in autophagic lysosome reformation, by sensing cellular stress levels. Therefore, autophagy–endocytosis crosstalk may be significant and implicates a novel endocytic regulatory pathway of autophagy. Moreover, endocytosis has a pivotal role in the intake of signalling molecules, which in turn activates cascades that can result in pathophysiological conditions. This review discusses the basic mechanisms of this crosstalk and its implications in order to identify potential novel therapeutic targets for various human diseases.     

Effect of Calmodulin Antagonists on Endocytosis and Intracellular Transport of Ricin in Polarized MDCK Cells

The effect of calmodulin antagonists on endocytosis, transcytosis, recycling, and transport to the Golgi apparatus from both the apical and the basolateral plasma membrane of polarized Madin–Darby canine kidney cells has been investigated by using the plant toxin ricin as a membrane marker. The calmodulin antagonists trifluoperazine andN-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) stimulated apical endocytosis of ricin, whereas basolateral endocytosis was unaffected. A stimulation of the apical uptake of the fluid-phase marker horseradish peroxidase by calmodulin antagonists was also found both by biochemical and by ultrastructural studies. Furthermore, W-7 reduced the recycling of ricin to the apical plasma membrane, whereas the recycling to the basolateral plasma membrane was not changed. Transport of ricin to the Golgi apparatus was also selectively affected by the calmodulin antagonist W-7. After basolateral endocytosis of ricin, transport to the Golgi apparatus was reduced, whereas after apical endocytosis the fraction of endocytosed ricin transport to the Golgi apparatus was increased. Transcytosis of ricin from the basolateral to the apical pole was increased in the presence of calmodulin antagonists, whereas these compounds did not have any significant effect on the apical to basolateral transcytosis. Thus, the results obtained indicate that calmodulin is involved in regulation of apical endocytosis and recycling as well as in transcytosis of ricin from the basolateral plasma membrane. Furthermore, the data suggest that calmodulin plays a role in regulation of ricin transport to the Golgi apparatus.     

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.     

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.     

Cis- and trans-acting functions required for endocytosis of the yeast pheromone receptors

The Saccharomyces cerevisiae a-factor receptor (STE3) is subject to two modes of endocytosis: a constitutive process that occurs in the absence of ligand and a regulated process that is triggered by binding of ligand. Both processes result in delivery of the receptor to the vacuole for degradation. Receptor mutants deleted for part of the COOH- terminal cytoplasmic domain are disabled for constitutive, but not ligand-dependent internalization. Trans-acting mutants that impair constitutive endocytosis have been isolated. One of these, ren1-1, is blocked at a late step in the endocytic pathway, as receptor accumulates in a prevacuolar endosome-like compartment. REN1 is identical to VPS2, a gene required for delivery of newly synthesized vacuolar enzymes to the vacuole. Based on this identity, we suggest a model in which the transport pathways to the vacuole--the endocytic pathway and the vacuolar biogenesis pathway--merge at an intermediate endocytic compartment. As receptor also accumulates at the surface of ren1 cells, receptor may recycle from the putative endosome to the surface, or REN1 may also be required to carry out an early step in endocytosis.