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.     

Processing of vasoactive intestinal peptide and transferrin in human cancerous colonic cells.

Endocytosis of vasoactive intestinal peptide (VIP) and of transferrin (Tf) was comparatively studied in human cancerous colonic HT-29 cells. Cellular depletion in potassium inhibits the internalization of VIP (23%) and to a greater extent (42%) that of Tf. This indicates that clathrin-coated pits are also involved, at least in part, in VIP uptake. The distribution of 125I-Tf- or 125I-VIP-containing vesicles in sucrose gradients revealed low and high density vesicle subpopulations. The low density vesicle subpopulation represented a transient compartment from which incoming vesicles containing N-leucyl-beta naphthylamidase were recycled back to the membrane while those containing beta-hexosaminidase (HA) and ligand were mostly transferred into the high density compartment. Subsequent fusion of the latter with heavy vesicles was demonstrated by the shift of HA and ligand with vesicles that had been prelabeled with horseradish peroxidase (HRP). Simultaneous internalization of Tf-HRP and 125I-VIP showed that both the low and high density vesicle subpopulations comprised of two types of VIP-containing vesicle, as confirmed by the density shift reaction: two-thirds of VIP shifted with the Tf-HRP-containing vesicles to denser fractions and the remaining was found with unshifted vesicles. These findings indicate that the VIP-receptor complex processing in HT-29 cells follows two routes, the major route being common with Tf endocytosis.     

Monensin inhibits intracellular dissociation of asialoglycoproteins from their receptor

Treatment of short-term monolayer cultures of rat hepatocytes with the proton ionophore, monensin, abolishes asialoglycoprotein degradation, despite little effect of the drug on either surface binding of ligand or internalization of prebound ligand. Centrifuging cell homogenates on Percoll density gradients indicates that, as a result of monensin treatment, ligand does not enter lysosomes but sediments instead in a lower density subcellular fraction that is likely an endocytic vesicle. Analyzing the degree of receptor association of intracellular ligand revealed that monensin prevents the dissociation of the receptor-ligand complex that normally occurs subsequent to endocytosis. The weak base, chloroquine, also blocks this intracellular dissociation. Evidence from sequential substitution experiments is presented, indicating that monensin and chloroquine act at the same point in the sequence of events leading to ligand dissociation. These data are discussed in terms of a pH-mediated dissociation of the receptor-ligand complex within a prelysosomal endocytic vesicle.     

Recycling of the asialoglycoprotein receptor in isolated rat hepatocytes. ATP depletion blocks receptor recycling but not a single round of endocytosis

Continuous endocytosis of 125I-asialo-orosomucoid (ASOR) mediated by the galactosyl receptor in rat hepatocytes is a cyclic process. 125I-ASOR-receptor complexes are internalized, processed, and the ligand is degraded while the receptor is returned to the cell surface for reutilization. Since a true cycle has a thermodynamic requirement for the input of external energy, we examined the effects of changes in intracellular ATP levels on the function of the receptor cycle. Hepatocytes were depleted of ATP to various extents prior to endocytosis by incubating cells at 15 degrees C in the presence of 2 mM NaF and 0-20 mM NaN3. A luciferase-luciferin bioluminescence assay was used to quantitate the amount of cellular ATP. ATP-depleted cells were allowed to bind 125I-ASOR at 0 degrees C, washed through discontinuous Percoll gradients, and only viable cells were isolated and incubated at 37 degrees C to initiate a synchronous single round of endocytosis. The extent of internalization of this surface-bound 125I-ASOR was unaffected by an ATP depletion to less than 1% of the control level. The rate of internalization of surface-bound ligand was unaffected until the ATP levels decreased to 30% or less; at greater than 98% ATP depletion the initial rate decreased by a maximum of 55% and the kinetics became biphasic. In contrast, continuous endocytosis in the presence of excess ASOR was inhibited by only a 25% decline in cellular ATP content and demonstrated a very sharp threshold response to changing ATP levels. Continuous endocytosis, which requires receptor recycling, was completely inhibited when the total cellular ATP level decreased by only 40%. We conclude that the internalization phase of endocytosis is not dependent on ATP but that the processing and/or externalization phases of the complete receptor cycle are either directly or indirectly dependent on ATP and very sensitive to changes in cellular ATP content.     

Effect of an vacuolar proton pump inhibitor bafilomycin A1 on the intracellular processing of markers for receptor-mediated and liquid phase endocytosis

By means of subcellular fractionation in density Percoll gradients, immunoblotting and immunofluorescense, the effect of BafA1 on endocytosis of EGF-receptor complexes and horse radish peroxidase (HRP) in A431, HER14 and HC11 cell lines was studied. It was shown that the pretreatment of all used cell lines with BafA1 completely inhibited EGF degradation, but did not interfere with the delivery of significant portion of EGF-receptor complexes to late endosomes and lysosomes and transition of the receptor to juxtranuclear region. At the same time, BafA1 was found to dramatically inhibit the delivery of fluid phase marker HRP to late endosomes of A431 cells. The BafA1 effect on endocytosis of high concentrations of EGF was similar to that on HRP endocytosis. Regulatory mechanisms of early-to-late endosomal compartment transition are discussed.     

Demonstration of an intact complex of epidermal growth factor and its receptor in the endosomes of A-431 cells

The compartmentalization of the epidermal growth factor (EGF) receptors in A-431 cells was studied using centrifugation of the microsomal fraction of these cells in continuous Percoll gradient. The existence of an intact (non-degraded) EGF receptor in plasma membrane and endosome fraction was demonstrated by electrophoretic analysis of in vitro phosphorylated Percoll fractions. No phosphorylated receptor was revealed in lysosomal fraction by this method. The existence of non dissociated EGF-receptor complexes in intracellular compartments 30 minutes after the start of internalization was proven using a synthesized photoreactive labeled EGF derivative (125I-EGF-SANAH). The removing of pH gradient in organellar membranes by 10 mkM of monensin did not affect dissociation from its receptor. The data obtained proved the existence of non-dissociated and non-degraded EGF-receptor complexes in the endosomal compartment of A-431 cells.     

Compartmentalization dynamics of the epidermal growth factor in A431 cells

Dynamics of compartmentalization of epidermal growth factor (EGF) in human carcinoma A431 cells during the first hour after initiation of endocytosis was examined by methods of the organelle fractionation on a 20% Percoll gradient and of the microfluorimetric visualization of endocytosis of rhodamine-labeled EGF (EGF-R). EGF was revealed in small vesicles localized in the peripheral region of cytoplasm in a few minutes after endocytosis initiation. During centrifugation in Percoll these vesicles (endosomes), with an average density of 1.038 g/ml, were seen co-sedimented with Golgi membranes. By one hour after initiation of endocytosis, EGF-R was accumulated in perinuclear zone, in a trans-Golgi region, as numerous big luminous centres that were apparently MB-endosomes and had the same density in Percoll as did small peripheral endosomes. Such centres appeared in several cells already within 5-10 minutes. In A431 cells EGF did not reach lysosomes within 60 minutes, because no accumulation of 125I-EGF was shown in lysosome corresponding regions of Percoll gradient (average density 1.070 g/ml).     

Sorting of endocytosed transferrin and asialoglycoprotein occurs immediately after internalization in HepG2 cells

After receptor-mediated uptake, asialoglycoproteins are routed to lysosomes, while transferrin is returned to the medium as apotransferrin. This sorting process was analyzed using 3,3'-diaminobenzidine (DAB) cytochemistry, followed by Percoll density gradient cell fractionation. A conjugate of asialoorosomucoid (ASOR) and horseradish peroxidase (HRP) was used as a ligand for the asialoglycoprotein receptor. Cells were incubated at 0 degree C in the presence of both 131I-transferrin and 125I-ASOR/HRP. Endocytosis of prebound 125I-ASOR/HRP and 131I-transferrin was monitored by cell fractionation on Percoll density gradients. Incubation of the cell homogenate in the presence of DAB and H2O2 before cell fractionation gave rise to a density shift of 125I-ASOR/HRP-containing vesicles due to HRP-catalyzed DAB polymerization. An identical change in density for 125I-transferrin and 125I-ASOR/HRP, induced by DAB cytochemistry, is taken as evidence for the concomitant presence of both ligands in the same compartment. At 37 degrees C, sorting of the two ligands occurred with a half-time of approximately 2 min, and was nearly completed within 10 min. The 125I-ASOR/HRP-induced shift of 131I-transferrin was completely dependent on the receptor-mediated uptake of 125I-ASOR/HRP in the same compartment. In the presence of a weak base (0.3 mM primaquine), the recycling of transferrin receptors was blocked. The cell surface transferrin receptor population was decreased within 6 min to 15% of its original size. DAB cytochemistry showed that sorting between endocytosed 131I-transferrin and 125I-ASOR/HRP was also blocked in the presence of primaquine. These results indicate that transferrin and asialoglycoprotein are taken up via the same compartments and that segregation of the transferrin-receptor complex and asialoglycoprotein occurs very efficiently soon after uptake.     

Macrophage endosomes contain proteases which degrade endocytosed protein ligands

Rabbit alveolar macrophages rapidly internalize and degrade mannosylated bovine serum albumin (125I-mannose-BSA). Trichloroacetic acid-soluble degradation products appear in the cells as early as 6 min after uptake at 37 degrees C, and in the extracellular medium after 10 min. Incubation of endocytic vesicles containing this ligand in isotonic buffers at pH 7.4 + ATP resulted in intravesicular proteolysis, which was inhibited by monensin, nigericin, or ammonium chloride. At pH 5.0, degradation proceeded rapidly and was abolished by lysis of the vesicles with 0.1% Triton X-100. Readdition of lysosomes to the incubation mixture did not increase the rate of prelysosomal degradation. Proteolysis of 125I-mannose-BSA was optimal at pH 4.5, and inhibited by low concentrations of the cathepsin D inhibitor pepstatin A. After subcellular fractionation of the macrophages on Percoll gradients, 125I-mannose-BSA sedimented with prelysosomal vesicles and was not transported to secondary lysosomes. Addition of pepstatin A to extracellular medium during internalization of prebound 125I-mannose-BSA partially inhibited degradation of ligand, and resulted in transfer of undegraded 125I-mannose-BSA to lysosomes after 20 min. Using 125I-bovine serum albumin as a substrate for the protease in the presence of 0.1% Triton X-100, we have shown that as much as 36% of the total pepstatin A-sensitive activity sediments with nonlysosomal membranes. After intraendosomal iodination using lactoperoxidase, a labeled protease was isolated by affinity chromatography on pepstatin-agarose. The labeled protease, which had a subunit size of 46 kDa, was detected in endocytic vesicles after 5 min of internalization. These results suggest that a cathepsin D-like protease is responsible for the degradation of 125I-mannose-BSA in macrophages, and that this ligand is degraded in a prelysosomal vesicle.     

Localization of the epidermal growth factor (EGF) receptor within the endosome of EGF-stimulated epidermoid carcinoma (A431) cells

We have followed the internalization pathway of both epidermal growth factor (EGF) and its receptor in human epidermoid carcinoma (A431) cells. Using EGF conjugated with horseradish peroxidase and anti-receptor monoclonal antibodies (TL5 and EGFR1) coupled either directly or indirectly to colloidal gold we have identified an extensive elaboration of endosomal compartments, consisting of a peripheral branching network of tubular cisternae connected to vacuolar elements that contain small vesicles and a pericentriolar compartment consisting of a tubular cisternal network connected to multivesicular bodies. Immunocytochemistry on frozen thin sections using receptor-specific antibody-gold revealed that at 4 degrees C in the presence of EGF, receptors were mainly on the plasma membrane and, to a lesser extent, within some elements of both the peripheral and pericentriolar endosomal compartments. Upon warming to 37 degrees C there was an EGF-dependent redistribution of most binding sites, first to the peripheral endosome compartment and then to the pericentriolar compartment and lysosomes. Upon warming only to 20 degrees C the ligand-receptor complex accumulated in the pericentriolar compartment. Acid phosphatase cytochemistry identifies hydrolytic activity only within secondary lysosomes and trans cisternae of the Golgi stacks. Together these observations suggest that the prelysosomal endosome compartment extends to the pericentriolar complex and that the transfer of EGF receptor complexes to the acid phosphatase-positive lysosome involves a discontinuous, temperature-dependent step.     

Transferrin and iron distribution in subcellular fractions of K562 cells in the early stages of transferrin endocytosis.

Iron distribution in subcellular fractions was investigated at different times after a single cohort of 59Fe-125 I-labeled transferrin (Tf) endocytosis in K562 cells. Cell homogenates prepared by hypotonic lysis and deoxyribonuclease (DNAase) treatment were fractionated on Percoll density gradients. Iron-containing components in the postmitochondrial supernatant were further fractionated according to their molecular weight using gel chromatography and membrane filtration. In the initial phases of endocytosis, both iron and Tf were found in the light vesicular fraction. After 3 min the labels diverged, with iron appearing in the postmitochondrial supernatant and Tf in the heavy fraction containing mitochondria, lysosomes and nuclei. Iron released from Tf-containing vesicles appeared both in low- and high-molecular-weight fractions in the postmitochondrial supernatant. After 5 min of endocytosis 59Fe activity in the low-molecular-weight fraction remained constant and 59Fe accumulated in a high-molecular-weight fraction susceptible to desferrioxamine chelation. After 10 min, 59Fe radioactivity in this fraction decreased and a majority of cytosolic 59Fe was found in ferritin. These results do not support the concept of the cytosolic low-molecular-weight iron pool as a kinetic intermediate between transferrin and ferritin iron in K562 cells.     

Epidermal growth factor stimulates fluid phase endocytosis in human fibroblasts through a signal generated at the cell surface

We have investigated the stimulation of fluid phase endocytosis by epidermal growth factor (EGF) in normal human fibroblasts using ¹²⁵I-labeled polyvinylpyrrolidone (¹²⁵I-PVP) as a fluid phase marker. We found that EGF initially induced a thereefold increase in the rate of ¹²⁵I-PVP uptake. This initial burst of fluid uptake terminated within 10 min. Thereafter, the rate of fluie uptake in EGF-treated cells was approximately 40% higher than in control cells. To identify the cellular site of EGF action in stimulating fluid phase endocytosis, we examined the kinetics of the induction of this response as well as the kinetics of cell surface binding and internalization of ¹²⁵I-EGF. Although there was no detectable lag between binding of EGF to the cell surface and its internalization, the kinetics of the two processes were quite different. Significantly, the kinetics of induction of ¹²⁵I-PVP uptake matched the kinetics of binding of ¹²⁵I-EGF to its cell surface receptors, indicating that the signal for the increase in fluid phase endocytosis is generated at the cell surface. To determine if EGF-stimulated fluid phase endocytosis was related to EGF-stimulated endocytosis of its own receptor, we compared the EGF dose dependency and time course of the two processes. Although the stimulated endocytosis of the EGF receptor was not saturable with respect to the concentration of EGF used, the stimulation of fluid phase endocytosis was half maximal at an EGF concentration of 1 ng/ml and saturated at a concentration of 5 ng/ml. Also, the stimulation of fluid phase endocytosis was sevenfold greater initially after adding EGF than after a 30-min continuous incubation with the hormone, whereas the enhanced clearance of the EGF receptor did not change during this time period. We conclude that the EGF-stimulated increase in fluid phase endocytosis is not directly coupled to EGF-stimulated endocytosis of its own receptor but instead to a separate signal generated at the cell surface.     

Divergent metabolism of human chorionic gonadotropin subunits within rat ovarian lysosomes

Pseudopregnant rats were injected with either native human chorionic gonadotropin or with (125I)-human chorionic gonadotropin and their ovarian homogenates fractionated on Percoll density gradients. The levels of alpha and beta subunits within subcellular fractions were measured using radioimmunoassays specific for each subunit. Radioactivity measurements of fractions obtained from rats injected with (125I)-human chorionic gonadotropin were used as a separate index of alpha subunit distribution. The alpha subunit was primarily restricted to a combined plasma membrane/prelysosomal vesicle fraction. Immunoreactive beta subunit was present at high concentrations within both this plasma membrane/prelysosomal vesicle fraction and within lysosomes. The striking difference in alpha and beta subcellular distribution may arise from differential sensitivities to lysosomal enzymes.     

Presence of a lysosomal enzyme, arylsulfatase-A, in the prelysosome-endosome compartments of human cultured fibroblasts

Although endosomes and lysosomes are associated with different subcellular functions, we present evidence that a lysosomal enzyme, arylsulfatase-A, is present in prelysosomal vesicles which constitute part of the endosomal compartment. When human cultured fibroblasts were subfractionated with Percoll gradients, arylsulfatase-A activity was enriched in three subcellular fractions: dense lysosomes, light lysosomes, and light membranous vesicles. Pulsing the cells for 1 to 10 min with the fluid-phase endocytic marker, horseradish peroxidase, showed that endosomes enriched with the marker were distributed partly in the light lysosome fraction but mainly in the light membranous fraction. By pulsing the fibroblasts for 10 min with horseradish peroxidase conjugated to colloidal gold and then staining the light membranous and light lysosomal fractions for arylsulfatase-A activity with a specific cytochemical technique, the endocytic marker was detected under the electron microscope in the same vesicles as the lysosomal enzyme. The origin of the lysosomal enzyme in this endosomal compartment was shown not to be acquired through mannose 6-phosphate receptor-mediated endocytosis of enzymes previously secreted from the cell. Together with our recent finding that the light membranous fraction contains prelysosomes distinct from bona fide lysosomes and was highly enriched with newly synthesized arylsulfatase-A molecules, these results demonstrate that prelysosomes also constitute part of the endosomal compartment to which intracellular lysosomal enzymes are targeted.     

Quantitative analysis of the endocytic system involved in hormone-induced receptor internalization

We have developed a quantitative method to evaluate the interaction between cell surface receptors and the endocytic apparatus. This method exploits occupancy-dependent changes in internalization rates that occur in cells expressing high numbers of receptors. We found that constitutive internalization of the transferrin receptor behaves as a simple, first order process that is unaltered by ligand. Internalization of the epidermal growth factor (EGF) receptor, however, behaves as a saturable, second order process that is induced by receptor occupancy. Internalization of EGF receptors occurs through at least two distinct pathways: a low capacity pathway that has a relatively high affinity for occupied receptors, and a low affinity pathway that has a much higher capacity. The high affinity pathway was observed in all cells having receptors with intrinsic tyrosine kinase activity. Mutant EGF receptors lacking kinase activity could not utilize the high affinity pathway and were internalized only through the low affinity one. Mutated receptors with decreased affinity for kinase substrates were also internalized at decreased rates through the high affinity, inducible pathway. In the case of vitellogenin receptors in Xenopus oocytes, occupied receptors competed more efficiently for internalization than empty ones. Insulin increased the endocytic capacity of oocytes for vitellogenin receptors. Similarly, serum increased the capacity of the inducible pathway for EGF receptors in mammalian cells. These data are consistent with a model of internalization in which occupied receptors bind to specific cellular components that mediate rapid internalization. Ligand-induced internalization results from an increase in the affinity of occupied receptors for the endocytic apparatus. Hormones can also indirectly regulate endocytosis by increasing the number of coated pits or their rate of internalization. The ability to dissect receptor-specific effects from cell-specific ones should be very useful in investigating the molecular mechanisms of receptor mediated endocytosis.     

Degradation of a monoclonal anti-mu chain antibody in a human surface IgM-positive B cell line starts in prelysosomal vesicle

The surface IgM-mediated endocytosis and intracellular transport of an anti-F(c mu)5 mAb was studied by using subcellular fractionation in sucrose gradients. The results of such experiments showed that antibody was initially endocytosed in vesicles of low density, and later transferred to a presumably lysosomal compartment of higher density. SDS-PAGE analysis of gradient fractions showed that high Mr degradation fragments of the endocytosed antibody were formed in the low density vesicles before terminal degradation could be recorded. The partial degradation of the antibody was not blocked by low temperature or enzyme inhibitors, such as leupeptin and benzyloxycarbonyl-phenylalanylalanine-diazomyethyl-ketone, all of which severely retarded terminal degradation. The data also suggested that the recycling of partially degraded antibody to the cell surface employed a pool of such low density prelysosomal vesicles.     

The structure of organelles of the endocytic pathway in hydrated cryosections of cultured cells

The structure of cellular organelles, in particular those involved in endocytosis, was studied by electron microscopy with hydrated cryosections. In this technique no chemical treatment is used, and the native structure of organelles can be observed in sections viewed at temperatures below -140 degrees C, using a cold stage accessory on the electron microscope. The compartments of the endocytic pathway were prelabeled with gold markers in the living cell, facilitating the identification of different structures in the cryosections. The structure of most identifiable cellular organelles, including those involved in endocytosis, appeared very similar in the hydrated cryosections to that seen after conventional plastic and cryosections of chemically fixed cells. In particular, the internal membranes of the structure we refer to as the prelysosomal compartment (Griffiths et al., Cell 52, 329-341 (1988] could be clearly visualized in these sections indicating that the organization of these membranes is not a consequence of the chemical fixation process.     

Multiple pathways for ligand internalization in rat hepatocytes. I: Effects of anoxia, phenylarsine oxide and monensin.

It has been suggested that there are multiple pathways for the cellular internalization of insulin. To investigate these pathways we have examined the effects of three perturbations of endocytosis on the insulin internalization process and have compared these effects with those obtained using an asialoglycoprotein, asialofetuin (Afet), and epidermal growth factor (EGF). Freshly isolated hepatocytes were incubated with radiolabeled ligands and internalization measured under conditions of anoxia to deplete cellular ATP, in the presence of phenylarsine oxide (PAO) to inhibit endocytosis, and in the presence of monensin to interfere with endosomal acidification. Afet internalization essentially was blocked by all three treatment processes, while insulin internalization was inhibited approximately 40% in the presence of anoxia, and 54% in the presence of PAO. Monensin exhibited differential effects on internalization of high and low insulin concentrations. The effects of the treatment processes on EGF internalization were intermediate to those seen with Afet and insulin. These results suggest that insulin and EGF utilize routes of internalization exhibiting different energy requirements that may correspond to coated pit, non-coated pit, and fluid-phase internalization pathways. The observations with Afet internalization remain consistent with utilization of the coated pit pathway.     

Cortactin and dynamin are required for the clathrin-independent endocytosis of gammac cytokine receptor

Endocytosis is critical for many cellular functions. We show that endocytosis of the common gammac cytokine receptor is clathrin independent by using a dominant-negative mutant of Eps15 or RNA interference to knock down clathrin heavy chain. This pathway is synaptojanin independent and requires the GTPase dynamin. In addition, this process requires actin polymerization. To further characterize the function of dynamin in clathrin-independent endocytosis, in particular its connection with the actin cytoskeleton, we focused on dynamin-binding proteins that interact with F-actin. We compared the involvement of these proteins in the clathrin-dependent and -independent pathways. Thus, we observed that intersectin, syndapin, and mAbp1, which are necessary for the uptake of transferrin (Tf), a marker of the clathrin route, are not required for gammac receptor endocytosis. Strikingly, cortactin is needed for both gammac and Tf internalizations. These results reveal the ubiquitous action of cortactin in internalization processes and suggest its role as a linker between actin dynamics and clathrin-dependent and -independent endocytosis.     

The effect of vanadate on receptor-mediated endocytosis of asialoorosomucoid in rat liver parenchymal cells

Vanadate is a phosphate analogue that inhibits enzymes involved in phosphate release and transfer reactions (Simons, T. J. B. (1979) Nature 281, 337-338). Since such reactions may play important roles in endocytosis, we studied the effects of vanadate on various steps in receptor-mediated endocytosis of asialoorosomucoid labeled with 125I-tyramine-cellobiose (125I-TC-AOM). The labeled degradation products formed from 125I-TC-AOM are trapped in the lysosomes and may therefore serve as lysosomal markers in subcellular fractionation studies. Vanadate reduced the amount of active surface asialoglycoprotein receptors approximately 70%, but had no effect on the rate of internalization and retroendocytosis of ligand. The amount of surface asialoglycoprotein receptors can be reduced by lowering the incubation temperature gradually from 37 to 15 degrees C (Weigel, P. H., and Oka, J. A. (1983) J. Biol. Chem. 258, 5089-5094); vanadate affected only the temperature--sensitive receptors. Vanadate inhibited degradation of 125I-TC-AOM 70-80%. Degradation was much more sensitive to vanadate than binding; half-maximal effects were seen at approximately 1 mM vanadate for binding and approximately 0.1 mM vanadate for degradation. By subcellular fractionation in sucrose and Nycodenz gradients, it was shown that vanadate completely prevented the transfer of 125I-TC-AOM from endosomes to lysosomes. Therefore, the inhibition of degradation by vanadate was indirect; in the presence of vanadate, ligand did not gain access to the lysosomes. The limited degradation in the presence of vanadate took place in a prelysosomal compartment. Vanadate did not affect cell viability and ATP content.