Receptor-mediated endocytosis of transferrin and recycling of the transferrin receptor in rat reticulocytes

At 4 degrees C transferrin bound to receptors on the reticulocyte plasma membrane, and at 37 degrees C receptor-mediated endocytosis of transferrin occurred. Uptake at 37 degrees C exceeded binding at 4 degrees C by 2.5-fold and saturated after 20-30 min. During uptake at 37 degrees C, bound transferrin was internalized into a trypsin- resistant space. Trypsinization at 4 degrees C destroyed surface receptors, but with subsequent incubation at 37 degrees C, surface receptors rapidly appeared (albeit in reduced numbers), and uptake occurred at a decreased level. After endocytosis, transferrin was released, apparently intact, into the extracellular space. At 37 degrees C colloidal gold-transferrin (AuTf) clustered in coated pits and then appeared inside various intracellular membrane-bounded compartments. Small vesicles and tubules were labeled after short (5-10 min) incubations at 37 degrees C. Larger multivesicular endosomes became heavily labeled after longer (20-35 min) incubations. Multivesicular endosomes apparently fused with the plasma membrane and released their contents by exocytosis. None of these organelles appeared to be lysosomal in nature, and 98% of intracellular AuTf was localized in acid phosphatase-negative compartments. AuTf, like transferrin, was released with subsequent incubation at 37 degrees C. Freeze-dried and freeze-fractured reticulocytes confirmed the distribution of AuTf in reticulocytes and revealed the presence of clathrin-coated patches amidst the spectrin coating the inner surface of the plasma membrane. These data suggest that transferrin is internalized via coated pits and vesicles and demonstrate that transferrin and its receptor are recycled back to the plasma membrane after endocytosis.     

Intracellular transport of transferrin- and asialoorosomucoid-colloidal gold conjugates to lysosomes after receptor-mediated endocytosis

Proteins coupled to colloidal gold particles have been widely used to visualize the uptake and intracellular transport of specific ligands by receptor-mediated endocytosis. The intracellular route of lysosome-directed ligands such as asialoglycoproteins (ASGP) are apparently unaltered by conjugation to gold, but the pathway of transferrin, a ligand that normally recycles to the cell surface, was reported to be altered by conjugation to 15-20 nm gold. In this study, we sought to determine whether a smaller transferrin-gold probe would recycle, and whether it might enter the same endosomal and lysosomal compartments as does a larger, lysosome-directed ASGP gold probe by visualizing their simultaneous uptake in human hepatoma (HepG2) cells. In the same cells, endocytosis of fluid-phase protein was followed using the soluble tracer native ferritin; lysosomal compartments were identified by acid phosphatase cytochemistry; and cell surfaces were labeled with ruthenium red or cationized ferritin. During the first 10 min of uptake at 37 degrees C, specific receptor-bound ferrotransferrin (FeTf)-8 nm gold and asialoorosomucoid (ASOR)-20 nm gold were clustered together in coated pits and entered the same coated vesicles, smooth vesicles, and tubules in the peripheral cytoplasm. At later times, however, transferrin-gold did not return to the cell surface; unlike native transferrin, this gold probe accompanied ASOR-gold into multivesicular bodies (MVB). The MVBs that contained probes were at first devoid of acid phosphatase activity, but at 30 min, enzyme activity was detected in a few MVBs. Native ferritin was present, along with gold probes, in all compartments of the endocytic pathway. We conclude that the normal intracellular pathway of transferrin is altered by its association with a colloidal gold particle.     

Distribution of newly synthesized lysosomal enzymes in the endocytic pathway of normal rat kidney cells

We have investigated the distribution of newly synthesized lysosomal enzymes in endocytic compartments of normal rat kidney (NRK) cells. The mannose-6-phosphate (Man6-P) containing lysosomal enzymes could be iodinated in situ after internalization of lactoperoxidase (LPO) by fluid phase endocytosis and isolated on CI-MPR affinity columns. For EM studies, the ectodomain of the CI-MPR conjugated to colloidal gold was used as a probe specific for the phosphomannosyl marker of the newly synthesized hydrolases. In NRK cells, approximately 20-40% of the phosphorylated hydrolases present in the entire pathway were found in early endocytic structures proximal to the 18 degrees C temperature block including early endosomes. These structures were characterized by a low content of endogenous CI-MPR and were accessible to fluid phase markers internalized for 5-15 min at 37 degrees C. The bulk of the phosphorylated lysosomal enzymes was found in late endocytic structures distal to the 18 degrees C block, rich in endogenous CI-MPR and accessible to endocytic markers internalized for 30-60 min at 37 degrees C. The CI-MPR negative lysosomes were devoid of phosphorylated hydrolases. This distribution was unchanged in cells treated with Man6-P to block recapture of secreted lysosomal enzymes. However, lysosomal enzymes were no longer detected in the early endosomal elements of cells treated with cycloheximide. Immunoprecipitation of cathepsin D from early endosomes of pulse-labeled cells showed that this hydrolase is a transient component of this compartment. These data indicate that in NRK cells, the earliest point of convergence of the lysosomal biosynthetic and the endocytic pathways is the early endosome.     

Ultrastructural localization of steroid sulphatase in cultured human fibroblasts by immunocytochemistry: A comparative study with lysosomal enzymes and the mannose 6-phosphate receptor

Summary Immunocytochemistry was used to study the subcellular localization of steroid sulphatase in cultured human fibroblasts. Ultra-thin cryosections were incubated with antibodies raised against steroid sulphatase purified from human placenta and immune complexes were visualized with gold probes as electron dense markers. Steroid sulphatase was found in rough endoplasmic reticulum, Golgi cisternae and in the trans-Golgi reticulum, where it co-distributes with lysosomal enzymes and the mannose 6-phosphate receptor. The enzyme was not detected in lysosomes. Steroid sulphatase was also found at the plasma membrane and in the endocytic pathway (i.e. coated pits, endosomes and multivesicular endosomes). These may be the sites where sulphated oestrogen precursors are hydrolysed. Also here, it co-localizes with lysosomal enzymes and the mannose 6-phosphate receptor. It is concluded that microsomal steroid sulphatase and lysosomal enzymes share several cellular compartments.     

Hemopexin joins transferrin as representative members of a distinct class of receptor-mediated endocytic transport systems

Receptor-mediated transport of heme by hemopexin in vivo and in vitro results in catabolism of heme but not the protein, suggesting that intact apohemopexin recycles from cells. However, until now, the intracellular transport of hemopexin by receptor-mediated endocytosis remained to be established. Biochemical studies on cultured human HepG2 and mouse Hepa hepatoma cells demonstrate that hemopexin is transported to an intracellular location and, after endocytosis, is subsequently returned intact to the medium. During incubation at 37 degrees C, hemopexin accumulated intracellularly for ca. 15 min before reaching a plateau while surface binding was saturated by 5 min. No internalization of ligand took place during incubation at 4 degrees C. These and other data suggest that hemopexin receptors recycle, and furthermore, incubation with monensin significantly inhibits the amount of cell associated of heme-[125I]hemopexin during short-term incubation at 37 degrees C, consistent with a block in receptor recycling. Ammonium chloride and methylamine were less inhibitory. Electron microscopic autoradiography of heme-[125I]hemopexin showed the presence of hemopexin in vesicles of the classical pathway of endocytosis in human HepG2 hepatoma cells, confirming the internalization of hemopexin. Colloidal gold-conjugated hemopexin and electron microscopy showed that hemopexin bound to receptors at 4 degrees C is distributed initially over the entire cell surface, including microvilli and coated pits. After incubation at 37 degrees C, hemopexin-gold is located intracellularly in coated vesicles and then in small endosomes and multivesicular bodies. Colocalization of hemopexin and transferrin intracellularly was shown in two ways. Radioiodinated hemopexin was observed in the same subcellular compartment as horseradish peroxidase conjugates of transferrin using the diaminobenzidine-induced density shift assay. In addition, colloidal gold derivatives of heme-hemopexin and diferric transferrin were found together in coated pits, coated vesicles, endosomes and multivesicular bodies. Therefore, hemopexin and transferrin act by a similar receptor-mediated mechanism in which the transport protein recycles after endocytosis from the cell to undergo further rounds of intracellular transport.     

Sequential processing of epidermal growth factor in early and late endosomes of rat liver.

We have used isolated perfused rat livers to examine the intracellular processing of 125I-epidermal growth factor (EGF) and to determine where in the endocytic pathway the hydrolases which degrade EGF are acting. Following uptake of 125I-EGF at 37 or 16 degrees C, subcellular fractions enriched in endosomes and lysosomes were isolated, and their 125I-EGF content was examined by reverse-phase high performance liquid chromatography. Three forms of EGF processed at their carboxyl termini are generated in endosomes. At 37 degrees C, EGF is first processed in early endosomes by a carboxypeptidase B-like protease and is further processed in late endosomes by a trypsin-like protease and then a carboxypeptidase B-like protease. At 16 degrees C, entry of EGF into late endosomes is slowed, and only the first processed form is generated over 60 min. Longer perfusions (180 min) at 16 degrees C result in some processing (7%) by proteases found in late endosomes. EGF-horseradish peroxidase cytochemistry confirmed that the additional processing detected at 180 min correlated with movement of EGF from tubulovesicular to multivesicular endosomes. These results, combined with in vitro incubations of EGF in isolated endosomal and lysosomal fractions, suggest that different proteases are active at selective points in the endocytic pathway and that the full complement of proteases needed for complete degradation of EGF is active only in lysosomes.     

Internalization and processing of transferrin and the transferrin receptor in human carcinoma A431 cells

The binding and subsequent intracellular processing of transferrin and transferrin receptors was studied in A431 cells using 125I-transferrin and a monoclonal antibody to the receptor (ATR) labeled with 125I and gold colloid. Using 125I-transferrin we have shown that, whereas at 37 degrees C uptake proceeded linearly for up to 60 min, most of the ligand that was bound was internalized and then rapidly returned to the incubation medium undegraded. At 37 degrees C, the intracellular half- life of the most rapidly recycled transferrin was 7.5 min. 125I-ATR displayed the same kinetics of uptake but following its internalization at 37 degrees C, it was partially degraded. At 22 degrees C and below, the intracellular degradation of 125I-ATR was selectively inhibited and as a result it accumulated intracellularly. Electron microscopy of conventional thin sections and of whole-cell mounts was used to follow the uptake and processing of transferrin receptors labeled with ATR- gold colloid complexes. Using a pulse-chase protocol, the intracellular pathway followed by internalized ATR gold-receptor complexes was outlined in detail. Within 5 min at 22 degrees C the internalized complexes were transferred from coated pits on the cell surface to a system of narrow, branching cisternae within the peripheral cytoplasm. By 15 min they reached larger, more dilated elements that, in thin section, appeared as irregular profiles containing small (30-50-nm diam) vesicles. By 30 min, the gold complexes were located predominantly within typical spherical multivesicular bodies lying in the peripheral cytoplasm, and by 40-60 min, they reached a system of cisternal and multivesicular body elements in the juxtanuclear area. At 22 degrees C, no other compartments became labeled but if they were warmed to 37 degrees C the gold complexes were transferred to lysosome- like elements. Extracting ATR-gold complexes with Triton X after a 30- min chase at 22 degrees C and purifying them on Sepharose-transferrin indicated that the internalized complexes remained bound to the transferrin receptor during their intracellular processing.     

Transferrin receptors and cation-independent mannose-6-phosphate receptors deliver their ligands to two distinct subpopulations of multivesicular endosomes

The distribution of transferrin receptors (Tf-R) was determined in Clone 9 hepatocytes and compared to that of 215 kDa, cation-independent mannose-6-phosphate receptors (M6P-R) by double labeling. Cells were allowed to take up exogenous human transferrin (Tf) for 5 to 30 min, after which Tf, Tf-R, and M6P-R were localized by immunofluorescence using specific antibodies. All these proteins were found to be concentrated in the juxtanuclear or Golgi region. When Clone 9 cells were treated with NH4Cl to trap M6P-R in endosomes (Brown, W. J., J. Goodhouse, M. G. Farquhar: J. Cell Biol. 103, 1235-1247 (1986)), the distribution of the two receptors differed: Tf-R remained the same as in controls, but M6P-R were localized in large vacuolated endosomes. To carry out double labeling experiments at the electron microscope level, transferrin gold conjugates (Tf-Au) were prepared, and M6P-R were detected by immunoperoxidase labeling. Tf-Au binding to the cell surface was specific as it was reduced approximately 70 to 79% in the presence of excess native Tf. When Clone 9 cells were incubated with Tf-Au at 37 degrees C for 5 to 30 min, or binding of Tf-Au was carried out at 4 degrees C followed by warming to 37 degrees C, Tf-Au was found within a peripheral tubulovesicular network and within multivesicular endosomes that were not labeled with anti-M6P-R. Other multivesicular endosomes of similar size and morphology were heavily labeled for M6P-R but contained little or no Tf-Au. Tf-Au and M6P-R were also found in separate endosomes in cells treated with NH4Cl. Native Tf was localized in the same compartments as Tf-Au by immunoperoxidase labeling of both Clone 9 cells and mouse myeloma cells. We conclude that in Clone 9 hepatocytes, Tf/Tf-R internalized from the cell surface and M6P-R bearing newly synthesized lysosomal enzymes from the Golgi deliver their ligands to two different subpopulations of multivesicular endosomes. The endosomal subpopulation visited by Tf/Tf-R is known to correspond kinetically to early endosomes. The endosomal subpopulation heavily labeled for M6P-R presumably represent a later endosomal compartment which serves as the junction point where endocytosed ligands and newly synthesized lysosomal enzymes enroute to lysosomes meet.     

Transport of acid phosphatase to lysosomes does not involve passage through the cell surface

In foregoing studies, we reported that LGP107, a major lysosomal membrane glycoprotein in the rat liver, distributes in and circulates continuously throughout the endocytic membrane system (endosomes, lysosomes and plasma membrane), in hepatocytes (1,2). In the present study we examined whether acid phosphatase (APase), an enzyme that is transported to lysosomes as a transmembrane protein, passes through the cell surface during intracellular transport, because transport of newly synthesized APase to lysosomes involves the passage of endosomes containing a ligand which is internalized via receptors on the cell surface and is finally dispatched to lysosomes for degradation (3). When localization of APase in rat hepatocytes was investigated by immunoelectron microscopy, APase was found to be localized in lysosomes and endosomes, but not in coated pits on the cell surface, which are positive for LGP107, and from which antibodies for LGP107 are internalized. Further, unlike LGP107, newly synthesized APase was not detected in plasma membranes isolated from livers of rats given [35S]methionine, and when cultured hepatocytes were exposed to 125I-labeled anti APase IgG at 37 degrees C, there was no transfer of the antibody to lysosomes even after 24 h incubation. Therefore, these results indicate that intracellular movement of APase does not involve cell surface passage in rat hepatocytes, and clearly differs from the recent report that human APase is transported to lysosomes via the cell surface in BHK cells transfected with its cDNA (4).     

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

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

Intracellular pathways of endocytosed transferrin and non-specific tracers in epithelial cells lining the rete testis of the rat

Summary The uptake and pathway of different markers and ligands for fluid-phase, adsorptive and receptor mediated endocytosis were analyzed in the epithelial cells lining the rete testis after their infusion into the lumen of these anastomotic channels. At 2 min after injection, diferric transferrin bound to colloidal gold was seen attached to the apical plasma membrane and to the membrane of endocytic coated and uncoated pits and vesicles. The injection of transferrin-gold in the presence of a 100-fold excess of unconjugated diferric transferrin revealed no binding or internalization of transferrin-gold. Similarly, apotransferrin-gold was neither bound to the apical plasma membrane nor internalized by these cells. These results thus indicate the presence of specific binding sites for diferric transferrin. At 5 min, internalized diferric transferrin-gold reached endosomes. At 15 and 30 min, the endosomes were still labeled but at these time intervals the transferrin-gold also appeared in tubular elements connected to or associated with these bodies or seen in close proximity to the apical plasma membrane. At 60 and 90 min, most of the transferrin-gold was no longer present in these organelles and was seen only exceptionally in secondary lysosomes. These results thus suggest that the tubular elements may be involved in the recycling of transferrin back to the lumen of the rete testis. The coinjection of transferrin-gold and the fluid-phase marker native ferritin revealed that both proteins were often internalized in the same endocytic pit and vesicle and shared the same endosome. However, unlike transferrin, native ferritin at the late time intervals appeared in dense multivesicular bodies and secondary lysosomes. When the adsorptive marker cationic ferritin and the fluid-phase marker albumin-gold were coinjected, again both proteins often shared the same endocytic pit and vesicle, endosome, pale and dense multivesicular body and secondary lysosomes. However, several endocytic vesicles labeled only with cationic ferritin appeared to bypass the endosomal and lysosomal compartments and to reach the lateral intercellular space and areas of the basement membrane. The rete epithelial cells, therefore, appear to be internalizing proteins and ligands by receptor-mediated and non-specific endocytosis which, after having shared the same endocytic vesicle and endosome, appear to be capable of being segregated and routed to different destinations.     

Transport of surface mannose 6-phosphate receptor to the Golgi complex in cultured human cells

The cation-independent mannose 6-phosphate receptor (MPRCI) functions in the packaging of both newly made and extracellular lysosomal enzymes into lysosomes. The subcellular location of MPRCI reflects these two functions; receptor is found in the Golgi complex, in endosomes, and on the cell surface. To learn about the intracellular pathway followed by surface receptor and to study the relationship between the receptor pools, we examined the entry of the surface MPRCI into Golgi compartments that contain sialyltransferase. Sialic acid was removed from surface-labeled K562 cultured human erythroleukemia cells by neuraminidase treatment. When the cells were returned to culture at 37 degrees C, surface MPRCI was resialylated by the cells with a half-time of 1-2 h. Resialylation was inhibited by reduced temperature, a treatment that allows surface molecules to reach endosomes but blocks further transport. These results indicate that surface MPRCI is transported to the sialyltransferase compartment in the Golgi complex. After culture at 37 degrees C, a small fraction (10-20%) of the resialylated receptor was found on the cell surface. Because a similar fraction of the total receptor pool is found on the cell surface, it is likely that cell surface MPRCI mixes with the cellular pool after resialylation. These data also support the idea that extracellular and newly made lysosomal enzymes are transported to lysosomes through a common compartment.     

Conjugates of colloidal gold with native and acetylated low density lipoproteins for ultrastructural investigations on receptor-mediated endocytosis by cultured human monocyte-derived macrophages

The morphological aspects of the binding and internalization of low density lipoproteins (LDL) and acetylated low density lipoproteins (AcLDL) by cultured human monocyte-derived macrophages were investigated. For this purpose, LDL and AcLDL were conjugated to 20 nm colloidal gold particles. After incubation of the cells with the conjugated lipoproteins at 4 degrees C some LDL- or AcLDL-gold complexes were found to be attached to the cell surface, but without characteristic localization. However, after incubation of the cells at 8 degrees C with either LDL-gold or AcLDL-gold, lipoprotein-gold complexes were present in clusters on the plasma membrane, often in coated pits. Cells incubated at 37 degrees C for various time periods showed internalization of both LDL- and AcLDL-gold complexes via small coated and non-coated vesicles and processing of the complexes in smooth-walled endosomes. When the cells were pulse-chased with LDL- or AcLDL-gold for 30 min at 37 degrees C, the gold conjugates occurred in dense bodies, probably lysosomes. The results suggest that although native and modified LDL are reported to be metabolized differently by macrophages, the morphological aspects of the endocytosis of LDL and AcLDL by cultured human monocyte-derived macrophages are similar.     

Inhibition of coated pit formation in Hep2 cells blocks the cytotoxicity of diphtheria toxin but not that of ricin toxin

It has been recently shown (Larkin, J. M., M. S. Brown, J. L. Goldstein, and R. G. W. Anderson, 1983, Cell, 33:273-285) that after a hypotonic shock followed by incubation in a K+-free medium, human fibroblasts arrest their coated pit formation and therefore arrest receptor-mediated endocytosis of low density lipoprotein. We have used this technique to study the endocytosis of transferrin, diphtheria toxin, and ricin toxin by three cell lines (Vero, Wi38/SV40, and Hep2 cells). Only Hep2 cells totally arrested internalization of [125I]transferrin, a ligand transported by coated pits and coated vesicles, after intracellular K+ depletion. Immunofluorescence studies using anti-clathrin antibodies showed that clathrin associated with the plasma membrane disappeared in Hep2 cells when the level of intracellular K+ was low. In the absence of functional coated pits, diphtheria toxin was unable to intoxicate Hep2 cells but the activity of ricin toxin was unaffected by this treatment. By measuring the rate of internalization of [125I]ricin toxin by Hep2 cells, with and without functional coated pits, we have shown that this labeled ligand was transported in both cases inside the cells. Hep2 cells with active coated pits internalized twice as much [125I]ricin toxin as Hep2 cells without coated pits. Entry of ricin toxin inside the cells was a slow process (8% of the bound toxin per 10 min at 37 degrees C) when compared to transferrin internalization (50% of the bound transferrin per 10 min at 37 degrees C). Using the indirect immunofluorescence technique on permeabilized cells, we have shown that Hep2 cells depleted in intracellular K+ accumulated ricin toxin in compartments that were predominantly localized around the cell nucleus. Our study indicates that in addition to the pathway of coated pits and coated vesicles used by diphtheria toxin and transferrin, another system of endocytosis for receptor-bound molecules takes place at the level of the cell membrane and is used by ricin toxin to enter the cytosol.     

Platelet-derived growth factor: morphologic and biochemical studies of binding, internalization, and degradation

Kinetic studies of binding and internalization of 125I-platelet-derived growth factor (PDGF) demonstrate that up to 15% of membrane-associated radioactivity is internalized within 2 minutes after warming to 37 degrees C in a variety of cell types. The T 1/2 for internalization is approximately 20 minutes. The T 1/2 for the subsequent appearance of degradation products in the culture medium is between 60-90 minutes following initiation of internalization. Internalization and lysosomal association of 125I-PDGF were confirmed by EM autoradiography. Quantitative studies using PDGF adsorbed to colloidal gold (gold-PDGF) demonstrate that 17% of the cell-associated sites are along coated regions of the plasma membrane (1.0 sites/micron), while 82% are associated with noncoated membrane (0.2 sites/micron). There is a significant redistribution of the gold-PDGF complexes upon warming. Within 1-2 minutes at 37 degrees C, gold particles are found within endocytic vesicles, endosomes (0.09-0.3 micron diameter), and lysosomes (greater than 0.2 micron diameter). At this time the vesicle/endosome compartment comprises 15% of the total sites and contains 0.9 sites per micron2 of surface area. The lysosomes account for 8% of the total sites and contain 0.8 sites per micron2 of surface area. Simultaneously, there is an increase in the number of gold-PDGF binding sites within coated-pits (1.6 sites/micron, 18% of the total sites) and a decrease along noncoated regions of the membrane (0.11 sites/micron, 58% of the total sites). After 15 minutes at 37 degrees C, 26% of the total sites (1.4 sites/micron2) are highly concentrated within lysosomes, while sites in the vesicle/endosome compartment remain constant. At the same time, binding sites within coated pits decrease substantially (0.5 sites/micron, 4% of the total sites), while the number of sites along noncoated regions of the membrane remain constant. Gold-PDGF was not observed associated with the Golgi complex at any time up to 120 minutes following warming. We conclude that gold-PDGF is processed via both receptor-mediated and nonspecific endocytosis and follows an intracellular pathway comparable to that followed by some other protein ligands.     

Molecules internalized by clathrin-independent endocytosis are delivered to endosomes containing transferrin receptors

We have previously demonstrated that the preendosomal compartment in addition to clathrin-coated vesicles, comprises distinct nonclathrin coated endocytic vesicles mediating clathrin-independent endocytosis (Hansen, S. H., K. Sandvig, and B. van Deurs. 1991. J. Cell Biol. 113:731-741). Using K+ depletion in HEp-2 cells to block clathrin- dependent but not clathrin-independent endocytosis, we have now traced the intracellular routing of these nonclathrin coated vesicles to see whether molecules internalized by clathrin-independent endocytosis are delivered to a unique compartment or whether they reach the same early and late endosomes as encountered by molecules internalized with high efficiency through clathrin-coated pits and vesicles. We find that Con A-gold internalized by clathrin-independent endocytosis is delivered to endosomes containing transferrin receptors. After incubation of K(+)- depleted cells with Con A-gold for 15 min, approximately 75% of Con A- gold in endosomes is colocalized with transferrin receptors. Endosomes containing only Con A-gold may be accounted for either by depletion of existing endosomes for transferrin receptors or by de novo generation of endosomes. Cationized gold and BSA-gold internalized in K(+)- depleted cells are also delivered to endosomes containing transferrin receptors. h-lamp-1-enriched compartments are only reached occasionally within 30 min in K(+)-depleted as well as in control cells. Thus, preendosomal vesicles generated by clathrin-independent endocytosis do not fuse to any marked degree with late endocytic compartments. These data show that in HEp-2 cells, molecules endocytosed without clathrin are delivered to the same endosomes as reached by transferrin receptors internalized through clathrin-coated pits.     

Transferrin recycling and dextran transport to lysosomes is differentially affected by bafilomycin,nocodazole, and low temperature

The effects of bafilomycin, nocodazole, and reduced temperature on recycling and the lysosomal pathway have been investigated in various cultured cell lines and have been shown to vary dependent on the cell type examined. However, the way in which these treatments affect recycling and transport to lysosomes within the same cell line has not been analyzed. In the current study, we used fluorophore-labeled transferrin and dextran as typical markers for the recycling and the lysosomal pathways, respectively, to explore the morphology and the intravesicular pH of endocytic compartments in HeLa cells. The V-ATPase inhibitor bafilomycin selectively inhibited the transport of marker destined for lysosomal degradation in early endosomes, whereas the transport of transferrin to the perinuclear recycling compartment (PNRC) still occurred. The kinetics of transferrin acidification was found to be biphasic, indicative of fast and slow recycling pathways via early endosomes (pH 6.0) and PNRC (pH 5.6), respectively. Furthermore, the disruption of microtubules by nocodazole blocked the transport of transferrin to the PNRC in early endosomes and of lysosome-directed marker into endosomal carrier vesicles. In contrast, incubation at 20°C affected the lysosomal pathway by causing retention of internalized dextran in late endosomes and a delay in transferrin recycling. Taken together, these data clearly demonstrate, for the first time, that the transferrin recycling pathway and transport of endocytosed material to lysosomes are differentially affected by bafilomycin, nocodazole, and low temperature in HeLa cells. Consequently, these treatments can be applied to investigate whether internalized macromolecules such as viruses follow a recycling or degradative pathway.This work was supported by grants from the Austrian Science Fund P12967 and P17590 to R.F.     

A Study of the Mechanism of Internalisation of Tetanus Toxin by Primary Mouse Spinal Cord Cultures

The fate of tetanus toxin bound to neuronal cells at 0 degree C was followed using an anti-toxin 125I-protein A assay. About 50% of surface-bound toxin disappeared within 5 min of warming cells to 37 degrees C. Experiments with 125I-toxin showed that much of this loss was due to dissociation of bound toxin into the medium. Some toxin was however rapidly internalised, and could be detected only by permeabilizing cells with Triton X-100 prior to assay. To investigate the mechanism of internalisation, tetanus toxin was adsorbed to colloidal gold. Toxin-gold was shown to be stable, and to recognise the same receptor(s) as free toxin. Quantitation of the distribution of toxin-gold particles bound to the cell body at 4 degrees C showed that it was concentrated in coated pits. After 5 min at 37 degrees C, toxin-gold appeared in coated vesicles, endosomes, and tubules. After 15 min, it was found largely in endosomes, and at 30 min in multivesicular bodies. The involvement of coated pits in internalisation of tetanus toxin, but not cholera toxin, was confirmed using the free toxins, anti-toxins, and protein A-gold. Toxin-gold also entered nerve terminals and axons via coated pits, accumulating in synaptic vesicles and intraaxonal uncoated vesicles, respectively.     

Binding and uptake of Col 1(I), a peptide capable of inhibiting collagen synthesis in fibroblasts

Col 1(I), a collagenase-resistant segment of the amino-terminal propeptide of pro alpha 1(I) chains, is known to inhibit collagen synthesis in cultured skin fibroblasts and also in a cell-free protein synthesizing system by reducing the translation of procollagen mRNA. These findings prompted us to explore the fate of exogenous Col 1(I) in the cellular processing of human skin fibroblasts using colloidal gold labeled protein (Col 1(I)-Au). Distribution of Col 1(I)-Au on the cell surface was studied by the platinum-carbon replication technique. Three different types of binding pattern could be observed: 1) Binding sites in the form of a fibrillar network, 2) those in the form of clusters, and 3) solitary bound gold conjugates. The latter two cases were determined to be specific. The intracellular routing of Col 1(I)-Au was studied by thin sections. Specifically bound gold conjugates were found in coated pits and after the initiation of the internalization process in coated vesicles and endosomes. Acid phosphatase cytochemistry revealed that only a small amount of Col 1(I)-Au is delivered to lysosomes. The bulk of gold conjugates is present even after prolonged incubation at 37 degrees C in acid phosphatase-negative compartments of the cell. Our data suggest a mechanism in which Col 1(I) initially is bound to the cell surface and subsequently internalized via the coated pit-coated vesicle pathway.     

Receptor-mediated endocytosis of immunoglobulin-coated colloidal gold particles in cultured mouse peritoneal macrophages

Endocytosis of immunoglobulin G (IgG)-coated colloidal gold particles in cultured mouse peritoneal macrophages was studied by scanning and transmission electron microscopy. At 4 degrees C, the tracers adhered to the plasma membrane and accumulated in coated pits located in the bottom of furrows or deep invaginations on the cell surface. In the presence of an excess of unlabeled mouse IgG, cellular binding of the tracer was reduced by 80 to 90%. After warming to 37 degrees C, surface-bound tracer particles were rapidly ingested and transported to small and large vesicles lacking membrane coat. From here, they were then passed over to multivesicular bodies and lysosomes characterized by their content of myelin-like figures and other inclusions. Double-labeling experiments with IgG-coated colloidal gold particles of two different sizes (20 and 5 nm diameter) indicated that the plasma membrane was depleted of binding sites after uptake of a polyvalent ligand. The restoration of the binding capacity was a slow process requiring ongoing protein synthesis. On the basis of these observations, a model for endocytosis of immune complexes in macrophages is presented. It includes the following four steps: IgG-containing macromolecular aggregates bind to specific receptors in the plasma membrane. These appear to be preclustered in coated pits or able to move laterally within the membrane even at 4 degrees C. The receptor-ligand complexes are internalized and transferred sequentially to larger uncoated vesicles or endosomes, multivesicular bodies, and lysosomes with inclusions of varying appearance. Receptors and ligands are degraded within the lysosomes.(ABSTRACT TRUNCATED AT 250 WORDS)