Insulin stimulates fluid-phase endocytosis and exocytosis in 3T3-L1 adipocytes

Fluid phase endocytosis by monolayers of 3T3-L1 adipocytes has been followed by measuring [14C]sucrose uptake, a well characterized pinocytic marker. Insulin, at a maximal stimulatory concentration, increased the pinocytic rate by 2-fold within 5 min of its addition; this activation persisted for at least 2 h. The dose-response curve for the enhancement of fluid-phase endocytosis by insulin was identical with that for the stimulation of hexose transport, as measured by the uptake of 2-deoxyglucose. The concentration of insulin eliciting half-maximal effects was 6 nM. These results suggest that activation of endocytosis and hexose uptake by insulin are triggered by the same signalling event. Insulin-activated pinocytosis was not dependent upon the increased metabolism of D-glucose that occurs in response to the hormone, since the stimulation of fluid-phase endocytosis occurred in the absence of 5 nM glucose. Fluid-phase exocytosis was examined by loading cells with [14C]sucrose for various times and then measuring tracer efflux. The rate of sucrose release was biphasic; a portion of the internalized sucrose was rapidly released from the cell (t1/2 approximately 5 min), whereas the remainder was released slowly (t1/2 approximately to 5 h). These results are consistent with a sequential two-compartment model in which the [14C] sucrose first enters a compartment from which about 70% of the sucrose is rapidly released back into the medium and the remaining 30% is transferred to a second compartment. Therefore, the true rate of endocytosis is much greater than the observed accumulation rates, except after short uptake times. Insulin increases the rate of sucrose efflux from both compartments as well as the rate of transfer from the first compartment to the second compartment by about 2-fold. Furthermore, insulin increased the apparent size of the first and second compartments by 1.6- and 3-fold, respectively. The lysosomotropic agent chloroquine (200 muM) had only a small effect on fluid movements in these cells. The rapid and prolonged stimulation of fluid-phase endocytosis and exocytosis by insulin are hitherto unrecognized effects of this hormone.     

Phorbol esters and horseradish peroxidase stimulate pinocytosis and redirect the flow of pinocytosed fluid in macrophages

Lucifer Yellow CH (LY) is an excellent probe for fluid-phase pinocytosis. It accumulates within the macrophage vacuolar system, is not degraded, and is not toxic at concentrations of 6.0 mg/ml. Its uptake is inhibited at 0 degree C. Thioglycollate-elicited mouse peritoneal macrophages were found to exhibit curvilinear uptake kinetics of LY. Upon addition of LY to the medium, there was a brief period of very rapid cellular accumulation of the dye (1,400 ng of LY/mg protein per h at 1 mg/ml LY). This rate of accumulation most closely approximates the rate of fluid influx by pinocytosis. Within 60 min, the rate of LY accumulation slowed to a steady-state rate of 250 ng/mg protein per h which then continued for up to 18 h. Pulse-chase experiments revealed that the reduced rate of accumulation under steady-state conditions was due to efflux of LY. Only 20% of LY taken into the cells was retained; the remainder was released back into the medium. Efflux has two components, rapid and slow; each can be characterized kinetically as a first-order reaction. The kinetics are similar to those described by Besterman et al. (Besterman, J. M., J. A. Airhart, R. C. Woodworth, and R. B. Low, 1981, J. Cell Biol. 91:716-727) who interpret fluid-phase pinocytosis as involving at least two compartments, one small, rapidly turning over compartment and another apparently larger one which fills and empties slowly. To search for processes that control intracellular fluid traffic, we studied pinocytosis after treatment of macrophages with horseradish peroxidase (HRP) or with the tumor promoter phorbol myristate acetate (PMA). HRP, often used as a marker for fluid-phase pinocytosis, was observed to stimulate the rate of LY accumulation in macrophages. PMA caused an immediate four- to sevenfold increase in the rate of LY accumulation. Both HRP and PMA increased LY accumulation by stimulating influx and reducing the percentage of internalized fluid that is rapidly recycled. A greater proportion of endocytosed fluid passes into the slowly emptying compartment (presumed lysosomes). These experiments demonstrate that because of the considerable efflux by cells, measurement of marker accumulation inaccurately estimates the rate of fluid pinocytosis. Moreover, pinocytic flow of water and solutes through cytoplasm is subject to regulation at points beyond the formation of pinosomes.     

Exocytosis of pinocytic contents by Chinese hamster ovary cells

The extent of exocytosis of pinocytic vesicle contents was studied in suspension-cultured Chinese hamster ovary (CHO) cells using horseradish peroxidase (HRP) as a pinocytic content marker. HRP was shown to be internalized via fluid-phase pinocytosis in CHO cells. After an HRP pulse of 2.5-10 min a rapid decrease of 30-50% in cell-associated HRP activity was observed within 10-20 min at 37 degrees C. During this time the loss of cell-associated HRP was accompanied by an equivalent increase in extracellular HRP. After this rapid exocytosis of HRP, the remaining peroxidase activity decreased with a t1/2 of 6-8 h, the known lysosomal half-life of HRP. In pulse-chase experiments HRP was chased into a nonexocytic compartment. Based on cell fractionation and electron microscopic experiments, this nonexocytic compartment was identified as a lysosome and the compartment from which exocytosis occurs as a pinosome. The occurrence of pinocytic content exocytosis in cultured fibroblasts suggests that exocytosis of pinocytic vesicle contents is a general phenomenon.     

Reassessment of fluid-phase endocytosis and diacytosis in monolayer cultures of human fibroblasts

We have investigated the kinetics of fluid-phase endocytosis and diacytosis in confluent monolayers of human fibroblasts by comparing the behavior of three markers that have been previously used to study this process: [14C]sucrose, 125I-labeled polyvinylpyrrolidone ([125I]PVP), and Lucifer Yellow. Three distinct kinetic compartments were observed with all markers. The first was relatively large (10-60 fl/cell), reached steady state within 15 min at 37 degrees C, and was rapidly lost from monolayers after removing the markers at 37 degrees C but not at 0 degree C. These properties indicate that this compartment is the same as that previously proposed to be the major intracellular compartment involved in diacytosis. However, this compartment is probably extracellular fluid trapped between cells since it is rapidly lost into the medium when the cells are either scraped or enzymatically removed from the culture dishes at 0 degree C. In addition, it very slowly undergoes both filling and emptying at 0 degree C. However, we did observe a second, much smaller, kinetic compartment (approximately 2 fl/cell) undergoing rapid diacytosis that does seem to be intracellular. A third compartment that we observed accumulates markers at a linear rate (10-20 fl cell-1 hr-1) and is not lost from cells even after incubation periods greater than 6 hr. The markers [14C]sucrose and [125I]PVP displayed very similar behavior with respect to all three compartments and yielded nearly linear long-term uptake rates, thus indicating that there is little if any absorbed component in their uptake. However, Lucifer Yellow displayed significantly higher incorporation rates and its uptake rate was strongly nonlinear, indicating its uptake in fibroblasts is predominantly adsorptive. Our observations indicate that the rate of fluid-phase endocytosis in fibroblasts is significantly less than previously reported and that any compartment involved in diacytosis is very small and turns over very rapidly. Significantly, we estimate that the constitutive internalization of clathrin-coated pits is sufficient to account for the majority of fluid-phase endocytosis and thus represents a major mechanism of membrane retrieval in these cells.     

Membrane flow during pinocytosis. A stereologic analysis

HRP has been used as a cytochemical marker for a sterelogic analysis of pinocytic vesicles and secondary lysosomes in cultivated macrophages and L cells. Evidence is presented that the diaminobenzidine technique (a) detects all vaculoes containing encyme and (b) distinguishes between incoming pinocytic vesicles and those which have fused with pre-existing lysosomes to form secondary lososomes. The HRP reactive pinocytic vesicle spaces fills completely within 5 min after exposure to enzyme, while the secondary lysosome compartment is saturated in 45--60 min. The size distribution of sectioned (profile) vaculoe diameters was measured at equilibrium and converted to actual (spherical) dimensions using a technique modified from Dr. S. D. Wicksell. The most important findings in this study have to do with the rate at which pinocytosed fluid and surface membrane move into the cell and on their subsequent fate. Each minute macrophages form at least 125 pinocytic vesicles having a fractional vol of 0.43% of the cell's volume and a fractional area of 3.1% of the cell's surface area. The fractional volume and surface area flux rates for L cells were 0.05% and 0.8% per minute respectively. Macrophages and L cells thus interiorize the equivalent of their cell surface area every 33 and 125 min. During a 3-period, the size of the secondary lysosome compartment remains constant and represents 2.5% of the cell volume and 18% of the surface area. Each hour, therefore, the volume and surface area of incoming vesicles is 10 times greater than the dimensions of the secondary lysosomes in both macrophages and L cells. This implies a rapid reduction in vesicle size during the formation of the secondary lysosome and the egress of pinocytosed fluid from the vacuole and the cell. In addition, we postulate that membrane components of the vacuole are subsequently recycled back to the cell surface.     

Effect of alterations in the size of the vacuolar compartment on pinocytosis in J774.2 macrophages

J774.2 macrophages cultured in medium containing 10 mg/ml sucrose accumulate the sugar by pinocytosis and become highly vacuolated, due to the sugar's osmotic effect within the vacuolar compartment. When such cells are incubated in medium containing 0.5 mg/ml invertase, the enzyme reaches the sucrose vacuoles by pinocytosis, then cleaves the sugar to more permeant monosaccharides. Within 4 hours, the vacuoles shrink to smaller, phase-dense organelles (Cohn and Ehrenreich, 1969, J. Exp. Med., 129:201). We have used this reversible expansion of the lysosomal compartment to address two questions: (1) Does the increased size of the lysosomal compartment affect pinocytic accumulation of solute, and (2) what is the fate of the vacuolar membrane and its soluble content during invertase-induced vacuole shrinkage? Using lucifer yellow (LY) as a probe for pinocytic fluid influx and efflux, we found that vacuolated cells accumulated 30–50% less LY than controls and returned to higher rates of pinocytosis after invertase-induced vacuole shrinkage. A similar reduction in LY accumulation was achieved after feeding cells latex beads to increase the size of the lysosomal compartment. Thus, treatments that increased the size of the lysosomal compartment reduced solute accumulation via pinocytosis. A dramatic shrinkage of LY-containing sucrose vacuoles followed pinocytosis of invertase. Despite this reduction in size of the LY-containing vacuoles, the overall rate of LY efflux did not increase significantly during invertase-induced vacuole collapse. Electron microscopy revealed that during shrinkage, the excess vacuolar membrane was compressed into whorled membranous organelles (residual bodies), with fluid markers (colloidal gold and, by inference, LY) trapped inside. The trapping of LY inside lysosomes as J774.2 macrophages returned to their normal dimensions indicates that nearly all of the surplus membrane contents were removed from circulation as well.     

Fluid-phase endocytosis by isolated rat adipocytes

We have developed an assay, which uses radiolabeled sucrose as the marker, to measure the rate of fluid-phase endocytosis in isolated rat adipocytes. In addition, the assay was adapted to allow measurement of the release of sucrose from previously loaded cells (fluid-phase exocytosis). Adipocytes take up sucrose at an approximately linear rate for at least 1.5 hours. A portion of the pinocytosed sucrose is rapidly (half-time about 20 minutes) returned to the medium. The minimal value for fluid uptake by endocytosis is 57 nl/10(6) cells-h at 37 degrees C; this value corresponds to the formation of 110,000 endocytic vesicles of 100-nm diameter per cell per hour and the internalization of about 20% of the plasma membrane per hour. Insulin caused a small and variable increase in the rate of sucrose uptake. The average increase of 31% from 11 experiments is statistically significant at the level of P less than 0.01. A small insulin effect upon the uptake of the calcium complex of [14C]EDTA was also observed. Since this complex was taken up at 2.5 times the rate of sucrose, it probably entered by a combination of fluid-phase and adsorptive pinocytosis. Insulin did not elicit a significant change in the rate of sucrose release from preloaded cells.     

Reversible pinocytosis of horseradish peroxidase in lymphoid cells

A detailed study of fluid phase endocytosis of horseradish peroxidase (HRP) in rat lymph node cells (LNC) is presented in this paper. Preliminary experiments have shown that HRP was internalized by non-receptor-mediated endocytosis and interacted minimally or not at all with plasma membrane of LNC, and can then be considered as a true fluid phase marker for these cells. Kinetics of uptake of HRP was found not to be linear with incubation time at 37 degrees C and deviation from linearity can be attributed to constant exocytosis of HRP. The kinetics of exocytosis cannot be described by a single exponential process. Rather, a minimum of two exponentials is required to account for exocytosis. This suggests that at least two intracellular compartments are involved in this process. The first turns over very rapidly with a t 1/2 release of about 3 min and is saturated after 10 min of exposure with HRP. The second, which turns over very slowly, is characterized by a t 1/2 release of about 500 min and accounts for the intracellular accumulation of HRP. Similar biphasic kinetics of exocytosis were observed with unfractionated LNC, with T lymphocyte-enriched LNC and with lymphocytes purified according to their density. This suggests that most, if not all, LNC are able to release HRP and that each cell type is endowed with the two intracellular compartments. Kinetics of uptake of HRP in these two compartments indicated that they are probably filled by two endocytic pathways, at least partially independent. Taken together, these results seem to indicate that a rapid membrane recycling occurs in lymphocytes. Furthermore, the weak base ammonium chloride and the carboxylic ionophore monensin were shown in our study to inhibit fluid phase endocytosis of HRP. The inhibition was time-dependent and required a preincubation of the cells with the drugs to be observed. Our results suggest that a perturbation of the vesicular traffic or a sequestration of membranes involved in HRP uptake is induced by these drugs. Under these conditions the release of cell-associated HRP was also reduced and to the same extent as the inhibition of uptake. Distribution of HRP between the two compartments and the t 1/2 release of HRP from either compartment were not perturbed. Taken together these results seem to indicate that exocytosis is not specifically affected by these drugs. Inhibition of uptake in drug-treated cells could result from a general decrease of membrane recycling or to the formation of smaller pinocytic vesicles with a different surface to volume ratio.     

Tubular lysosomes accompany stimulated pinocytosis in macrophages

A network of tubular lysosomes extends through the cytoplasm of J774.2 macrophages and phorbol ester-treated mouse peritoneal macrophages. The presence of this network is dependent upon the integrity of cytoplasmic microtubules and correlates with high cellular rates of accumulation of Lucifer Yellow (LY), a marker of fluid phase pinocytosis. We tested the hypothesis that the efficiency of LY transfer between the pinosomal and lysosomal compartments is increased in the presence of tubular lysosomes by asking how conditions that deplete the tubular lysosome network affect pinocytic accumulation of LY. Tubular lysosomes were disassembled in cells treated with microtubule-depolymerizing drugs or in cells that had phagocytosed latex beads. In unstimulated peritoneal macrophages, which normally contain few tubular lysosomes and which exhibit relatively inefficient transfer of pinocytosed LY to lysosomes, such treatments had little effect on pinocytosis. However, in J774 macrophages and phorbol ester-stimulated peritoneal macrophages, these treatments markedly reduced the efficiency of pinocytic accumulation of LY. We conclude that a basal level of solute accumulation via pinocytosis proceeds independently of the tubular lysosomes, and that an extended tubular lysosomal network contributes to the elevated rates of solute accumulation that accompany macrophage stimulation. Moreover, we suggest that the transformed mouse macrophage cell line J774 exhibits this stimulated pinocytosis constitutively.     

Pinocytosis and intracellular degradation of exogenous protein: modulation by amino acids

Intracellular degradation of exogenous (serum) proteins provides a source of amino acids for cellular protein synthesis. Pinocytosis serves as the mechanism for delivering exogenous protein to the lysosomes, the major site of intracellular degradation of exogenous protein. To determine whether the availability of extracellular free amino acids altered pinocytic function, we incubated monolayers of pulmonary alveolar macrophages with the fluid-phase marker, [14C]sucrose, and we dissected the pinocytic process by kinetic analysis. Additionally, intracellular degradation of endogenous and exogenous protein was monitored by measuring phenylalanine released from the cell monolayers in the presence of cycloheximide. Results revealed that in response to a subphysiological level of essential amino acids or to amino acid deprivation, (a) the rate of fluid-phase pinocytosis increased in such a manner as to preferentially increase both delivery to and size of an intracellular compartment believed to be the lysosomes, (b) the degradation of exogenously supplied albumin increased, and (c) the fraction of phenylalanine derived from degradation of exogenous albumin and reutilized for de novo protein synthesis increased. Thus, modulation of the pinosome-lysosome pathway may represent a homeostatic mechanism sensitive to the availability of extracellular free amino acids.     

Helicobacter pylori VacA cytotoxin: a probe for a clathrin-independent and Cdc42-dependent pinocytic pathway routed to late endosomes

The vacuolating cytotoxin VacA is a major virulence factor of Helicobacter pylori, a bacterium responsible for gastroduodenal ulcers and cancer. VacA associates with lipid rafts, is endocytosed, and reaches the late endocytic compartment where it induces vacuolation. We have investigated the endocytic and intracellular trafficking pathways used by VacA, in HeLa and gastric AGS cells. We report here that VacA was first bound to plasma-membrane domains localized above F-actin structures that were controlled by the Rac1 GTPase. VacA was subsequently pinocytosed by a clathrin-independent mechanism into cell peripheral early endocytic compartments lacking caveolin 1, the Rab5 effector early endosomes antigen-1 (EEA1) and transferrin. These compartments took up fluid-phase (as evidenced by the accumulation of fluorescent dextran) and glycosylphosphatidylinositol-anchored proteins (GPI-APs). VacA pinocytosis was controlled by Cdc42 and did not require cellular tyrosine kinases, dynamin 2, ADP-ribosylating factor 6, or RhoA GTPase activities. VacA was subsequently routed to EEA1-sorting endosomes and then sorted to late endosomes. During all these different endocytic steps, VacA was continuously associated with detergent resistant membrane domains. From these results we propose that VacA might be a valuable probe to study raft-associated molecules, pinocytosed by a clathrin-independent mechanism, and routed to the degradative compartment.     

Retention of pinocytized solute by CHO cell lysosomes correlates with molecular weight

We compared the exocytosis by Chinese hamster ovary (CHO) cells of a set of fluid-phase pinocytic tracers. The tracers were horseradish peroxidase (HRP), a glycoprotein of approximately 40 kDa, lucifer yellow (LuY), a 457 dalton, membrane-impermeant fluorescent dye, and glucose polymers ranging from sucrose through higher molecular weight, fluorescein isothiocyanate (FITC) dextrans. After a long term uptake (16-20 h), each of these tracers was localized to lysosomes. Exocytosis of the majority of the small molecule tracers, LuY and [14C] sucrose, was observed over a period of a few to several h. There was no significant exocytosis of 42 kDa FITC dextran or HRP during an 18-20 h chase, while lower molecular weight dextrans were exocytosed. After co-accumulation of LuY and HRP in lysosomes, only the low molecular weight marker was exocytosed. These observations suggest retention of endocytized solutes within lysosomes is dependent on molecular size and may be limited by the rate of diffusion of molecules into shuttle vesicles.     

Rapid stimulation of fluid-phase endocytosis and exocytosis by insulin, insulin-like growth factor-I, and epidermal growth factor in KB cells

Effects of growth factors on fluid-phase endocytosis and exocytosis in human epidermoid carcinoma KB cells were examined by measuring horseradish peroxidase (HRP) as a marker. Insulin, insulin-like growth factor-I (IGF-I), and epidermal growth factor (EGF) promoted HRP accumulation. They also stimulated the efflux of the preloaded HRP from the cells. From these results it follows that these growth factors stimulate the influx as well as the efflux of HRP, because the accumulation rate is the sum of the influx rate and the efflux rate. The stimulation of both HRP accumulation and HRP efflux was rapidly induced within 2-4 min of the addition of growth factors and persisted for at least 60 min. The concentrations eliciting half-maximal stimulatory effects of insulin, IGF-I, and EGF were about 5 X 10(-7), 1 X 10(-9), and 5 X 10(-10) M, respectively. aIR-3 (anti-type I IGF receptor antibody) completely blocked the stimulation of HRP accumulation by IGF-I but very slightly inhibited the stimulation by insulin. The 528 IgG (anti-EGF receptor antibody) inhibited the stimulation of HRP accumulation by EGF. These results indicated that each of these growth factors stimulates the HRP accumulation mediated by the corresponding (homologous) growth factor receptors. The rapid stimulation of fluid-phase influx and efflux may constitute one of the common early cellular responses to growth factors.     

Kinetics of fluid-phase pinocytosis in Dictyostelium discoideum amoebae

Kinetics of pinocytosis in Dictyostelium discoideum were investigated over an extended period of time (up to 6 hours) using fluorescein isothiocyanate (FITC)-dextran as a fluid-phase marker. FITC-dextran added to the medium accumulated rapidly inside the cells with a rate of influx equivalent to 9 microns3 of fluid/cell x min. After a period of about 90 min of uptake, the intracellular FITC-dextran level reached a plateau which corresponded to a strict balance between pinocytosis and exocytosis as shown both by efflux measurements and pulse experiments with (3H) dextran. At equilibrium, the amount of internalized marker reached a value equivalent to 790 microns3 of fluid taken up per amoeba, i.e. a volume paradoxically higher than the total aqueous space of the cell (520 microns3 ). FITC-dextran was thus markedly concentrated intracellularly. The endocytic compartment in which the intracellular FITC-dextran was concentrated could be completely washed out when FITC-dextran was removed from the external medium.     

Modelling of fluid-phase endocytosis kinetics in the amoebae of the cellular slime mouldDictyostelium discoideum. A multicompartmental approach

Fluid-phase endocytosis (pinocytosis) kinetics were studied inDictyostelium discoideum amoebae from the axenic strain Ax-2 that exhibits high rates of fluid-phase endocytosis when cultured in liquid nutrient media. Fluorescein-labelled dextran (FITC-dextran) was used as a marker in continuous uptake- and in pulse-chase exocytosis experiments. In the latter case, efflux of the marker was monitored on cells loaded for short periods of time and resuspended in marker-free medium. A multicompartmental model was developed which describes satisfactorily fluid-phase endocytosis kinetics. In particular, it accounts correctly for the extended latency period before exocytosis in pulse-chase experiments and it suggests the existence of some sorts of maturation stages in the pathway.     

A multicompartmental model of fluid-phase endocytosis in rabbit liver parenchymal cells.

Fluid-phase endocytosis was studied in isolated rabbit liver parenchymal cells by using 125I-poly(vinylpyrrolidone) (PVP) as a marker. First, uptake of 125I-PVP by cells was determined. Also, cells were loaded with 125I-PVP for 20, 60 and 120 min, and release of marker was monitored for 120-220 min. Then we used the Simulation, Analysis and Modeling (SAAM) computer program and the technique of model-based compartmental analysis to develop a mechanistic model for fluid-phase endocytosis in these cells. To fit all data simultaneously, a model with three cellular compartments and one extracellular compartment was required. The three kinetically distinct cellular compartments are interpreted to represent (1) early endosomes, (2) a prelysosomal compartment equivalent to the compartment for uncoupling of receptor and ligand (CURL) and/or multivesicular bodies (MVB), and (3) lysosomes. The model predicts that approx. 80% of the internalized 125I-PVP was recycled to the medium from the early-endosome compartment. The apparent first-order rate constant for this recycling was 0.094 min-1, thus indicating that an average 125I-PVP molecule is recycled in 11 min. The model also predicts that recycling to the medium occurs from all three intracellular compartments. From the prelysosomal compartment, 40% of the 125I-PVP molecules are predicted to recycle to the medium and 60% are transferred to the lysosomal compartment. The average time for recycling from the prelysosomal compartment to the medium was estimated to be 66 min. For 125I-PVP in the lysosomal compartment, 0.3%/min was transferred back to the medium. These results, and the model developed to interpret the data, predict that there is extensive recycling of material endocytosed by fluid-phase endocytosis to the extracellular environment in rabbit liver parenchymal cells.     

A quantitative study of pinocytosis and intracellular proteolysis in rat peritoneal macrophages.

A method for the culture of rat peritoneal macrophages in vitro is described, in which pinocytic uptake of colloidal [198 Au]gold, 125I--labelled poly(vinylpyrrolidone) and [14C]sucrose proceeds at contant and fairly reproducible rates for several hours. The rat of uptake of colloidal [198 Au]gold, which wxhibited some inter-batch variation, was approx. 100 times that of the other two substrates. Colloidal gold did not affect the rate of uptake of 125I-labelled poly(vinylpyrrolidone) and therefore its own high rate of uptake could not be attributed to a stimulation of the formation of pinocytic vesicles. It conclude that uptake of collodial gold is highly dependent on adsorption on binding sites on the plasma membrane. Uptake of formaldehyde-treated 125I-labelled bovine serum albumin was followed by the release of [125I]iodo-L-tyrosine into the culture medium and took place at a rate intermediate between those of collodial [198Au]gold and the other two non-digestible substrates, 125I-labelled poly(vinylpyrrolidone) and [14C]sucrose.     

Intralysosomal accumulation of polyanions. I. Fusion of pinocytic and phagocytic vacuoles with secondary lysosomes

The long-term exposure of macrophages to low concentrations of a number of polyanions leads to their accumulation in high concentration within secondary lysosomes. This was associated with enlargement of the lysosomes, the presence of membranous whorls, and intense toluidine blue staining of the organelles at pH 1.0. After the ingestion of a particulate load by these cells, newly formed phagocytic vacuoles failed to fuse with polyanion-laden lysosomes. The lack of fusion was evident in both fluorescence and electron micrographic studies which followed the transfer of acridine orange or Thorotrast from 2 degrees lysosomes to phagosomes. Agents that inhibited phagosome-lysosome (P-L) fusion included molecules containing high densities of sulfate, sulfonate, or carboxylate residues. Dextran sulfate (DS) in microgram/ml quantities was an excellent inhibitor, whereas nonsulfated dextran (D) was without effect at 1,000-fold higher concentrations. In contrast to their effects on P-L fusion, polyanions failed to influence the fusion of pinocytic vesicles with 2 degrees lysosomes. The uptake, intravacuolar distribution, and intralysosomal digestion of fluid-phase pinocytic markers were unaltered in lysosomes containing either D or DS. Furthermore, subcellular fractionation studies showed that the fluid-phase pinocytic marker HRP was efficiently transferred from pinosomes to large, dense 2 degrees lysosomes containing DS.     

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.     

Exchange kinetics and composition of endocytic membranes in terms of plasma membrane constituents: a morphometric study in macrophages

Intracellular membrane traffic, during endocytosis in mouse bone marrow-derived macrophages, was studied quantitatively by morphometric and kinetic analysis. Three functionally different markers were used: Horseradish peroxidase (HRP) served as a fluid-phase (FP) marker (1000 micrograms HRP/ml in the presence of mannan) or as a receptor-mediated (RM) membrane marker (25 micrograms HRP/ml) and, third, plasma membrane (PM) glycoconjugates, enzymatically labeled with [3H]galactose at the cell surface, served as a covalent membrane marker. The cell surface was labeled with [3H]galactose, followed by either FP or by RM uptake of HRP. The kinetics of the intracellular appearance of the markers were measured as the membrane area stained by HRP-reaction product and as the number of autoradiographic grains associated with these membranes. The following compartments were distinguished: PM, coated vesicles (VI), pinosomes or endosomes (VII), secondary lysosomes (VIII), and HRP-negative vesicles (EV). Tubular structures of VII became labeled with HRP only during RM uptake. The markers flowed first into VI and VII, and after 5 min into VIII. EV became labeled with the covalent membrane marker starting from 5 min. The ratio of autoradiographic grain number to HRP-stained membrane area remained constant with time although substantially different for the various compartments, viz. 100% (VI), 50% (VII and EV) and 30% (VIII) as compared to the PM (100%). This indicated that endosomes were only partially derived from internalized PM and that secondary lysosomes contained a substantial pool of PM constituents. The observed kinetics suggested that once every 30 to 40 min the entire PM was internalized, the bulk of which was recycled after 4 min from a prelysosomal compartment(s) leaving only 12 to 20% for recycling via membranes of secondary lysosomes after a residence time of 24 to 33 min.