Redistribution of cell surface transferrin receptors prior to their concentration in coated pits as revealed by immunoferritin labels

Summary Immunocytochemistry has been used to study distribution of cell surface transferrin receptors in erythroid, leukemic (K562) cells. The cells were fixed and labelled with monoclonal (OKT-9) anti-transferrin receptor antibodies; the antibody-labelled receptors were then detected by either immunofluoresceinor immunoferritin-antimouse-antibody conjugates. Typically, the immunoferritin labels were distributed diffusely at the non-coated regions of the cell surface as well as concentrated in the clathrincoated pits. To examine further this pattern of distribution, cells were labelled at 0° C and then warmed to 37° C for zero to 30 min prior to fixation. The majority of the immunoferritin labels were initially dispersed in small groups at the non-coated regions of the cell surface (mean = 6 immunoferritin labels/cluster), but larger groups were common subsequent to incubation at 37° C (mean = 13 immunoferritin labels/cluster). However, the size of immunoferritin labels in the coated pits was unchanged (mean = 12 immunoferritin labels/pit). Immunoferritin labels were typical in coated and uncoated vesicles l min after warming to 37° C, but common in endosomes, multivesicular bodies and lysosomes by 30 min. It appears that single cell-surface receptors form large aggregates prior to their concentration in coated pits. Coated vesicles, uncoated vesicles, and endosomal vacuoles may together form the non-lysosomal compartment where the internalized receptors might be dissociated from the ligands (antibodies).     

Quantitative ultrastructural analysis of receptor-mediated insulin uptake into adipocytes

Monomeric ferritin-insulin was used as an ultrastructural marker to determine by quantitative electron microscopy the time course and route of insulin uptake in rat adipocytes. To approximate steady state membrane binding conditions prior to any internalization, adipocytes were prefixed with glutaraldehyde and incubated for 30 min with 70 nM monomeric ferritin-insulin. Electron micrographs of these cells showed that the ferritin-insulin particles were predominantly in small groups of receptor sites on the plasma membrane and in pinocytotic-like invaginations of the plasma membrane. Significant amounts of ferritin-insulin were observed in cytoplasmic vesicles of unfixed cells as early as 2 min and in multivesicular bodies and lysosome-like structures within 5 to 10 min after the addition of the ligand. Ferritin-insulin accumulation reached steady state levels in the cytoplasmic vesicles in 5 to 10 min and in the lysosome-like structures in 15 min. Little ferritin-insulin was bound to coated pits, and the relative paucity of coated pits found in adipocytes suggested that these specialized endocytotic structures have a relatively insignificant role in insulin uptake in fat cells. Quantitative analysis of the uptake process suggested that a proportion of the insulin internalized by the cell may not be transported to lysosomes, but may be recycled along with the insulin receptor to the plasma membrane.     

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.     

Lysosomal acid phosphatase is internalized via clathrin-coated pits.

The presence of lysosomal acid phosphatase (LAP) in coated pits at the plasma membrane was investigated by immunocytochemistry in thymidine kinase negative mouse L-cells (Ltk-) and baby hamster kidney (BHK) cells overexpressing human LAP (Ltk-LAP and BHK-LAP cells). Double immunogold labeling showed that at various stages of invaginating coated pits LAP colocalized with clathrin and plasma membrane adaptors (HA-2 adaptors). Quantitation of the immunogold label showed similar density of wild-type LAP in coated over non-coated areas of the plasma membrane, whereas an internalization-deficient, truncated mutant of LAP which lacks the cytoplasmic tail was less efficiently included into coated pits. Internalization of anti-LAP antibodies into endosomal vesicles was accompanied by rapid dissociation of the coat proteins as shown by an immunofluorescence assay. The role of clathrin-coated vesicles in internalization of LAP was further corroborated by microinjecting monoclonal antibodies against clathrin or HA-2 adaptors into BHK-LAP cells. Internalization of LAP as detected by an immunofluorescence assay was transiently blocked by microinjected antibodies against clathrin or HA-2 adaptors, whereas unrelated antibodies did not affect internalization. These data suggest that LAP is included into clathrin-coated pits of the plasma membrane for rapid internalization.     

Coated and smooth vesicles participate in acetylcholine receptor transport

Summary The removal of the acetylcholine receptors (AChRs) from the surface of muscle cells serves as an important mechanism in the regulation of the AChR turnover rate. Our previous studies have shown that cultured myotubes contain coated pits and vesicles bearing -bungarotoxin (BTX)-binding sites (Bursztajn 1984; Bursztajn and Fischbach 1984). In this study we have used BTX conjugated to horseradish peroxidase (HRP) and quantitative electron microscopy to determine the intracellular pathway(s) of acetylcholine receptors during the internalization process. To accomplish this, cultured rat myotubes were incubated with BTX-HRP at 4° C after which cells were washed and incubated at 37° C for 0 min to 2 h. After warming the cells, coated pits, coated vesicles and smooth membraned vesicles containing the peroxidase reaction product were present. A threefold increase in coated vesicles containing the reaction product was observed 1 min after warming the cells. The number of smooth-membraned vesicles remained constant at this time point. However, 5 to 15 min after warming the cells, a fivefold increase in the number of smooth membraned vesicles was observed. After 1 h at 37° C the reaction product was present in the lysosomal like bodies, but was not observed in the Golgi complex or the small coated vesicles associated with the Golgi complex. Our observations indicate that there is a size segregation between those coated vesicles containing BTX-HRP reaction product and those in which reaction product is absent. Our studies also suggest that within minutes of AChR internalization coated vesicles lose their coat and become smooth-membraned vesicles.     

Serial section analysis of clathrin-coated pits in rat liver sinusoidal endothelial cells

Electron microscopy and serial sections were used to examine the shape of clathrin-coated pits in sinusoidal endothelial cells of rat livers. Livers were perfused at 4 degrees C with either concanavalin A-horseradish peroxidase (conA-HRP), or HRP alone, followed by warm-up to 37 degrees C and fixation with glutaraldehyde. Alternatively, the livers were perfused with HRP at 37 degrees C, followed by fixation. All tissue was preserved using a membrane contrast enhancement technique (R-OTO) consisting of sequential osmium-ferrocyanide, thiocarbohydrazide, and osmium-ferrocyanide treatment. Peroxidase reaction product was used to identify structures participating in endocytosis. One hundred and ninety-three clathrin-coated structures were examined. Sixty-six were from livers perfused with conA-HRP at 4 degrees C, 63 were from livers perfused with only HRP at 4 degrees C, and 64 were from livers perfused with HRP at 37 degrees C. These coated structures were morphologically classified into three categories: (a) flat pits; (b) cup-shaped pits; (c) pits with a narrow neck. No isolated coated vesicles were found. In cells perfused at 4 degrees C followed by warming to 37 degrees C, the percentage of coated pits found connected to the cell surface by narrow necks was 31%, using conA-HRP, and 27% using HRP alone. In cells perfused continuously at 37 degrees C, the percentage of coated pits with narrow neck connections was 21% using HRP alone. These results suggest that the formation of coated pits connected to the surface by narrow necks is not an artifact of cell type, of experimental protocol or of incubation with a lectin.     

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.     

Surface interactions and intracellular localization of cationic ferritin: similarity to 125I-insulin in 3T3-L1 adipocytes

We previously reported that in 3T3-L1 adipocytes 125I-insulin associates preferentially with microvilli and coated pits at low temperatures and early times of incubation. At higher temperatures it is internalized through a series of membrane limited intracellular compartments. In the present study, we used a high resolution probe, cationic ferritin (CF), to track adsorptive endocytosis in the 3T3-L1 adipocyte. We find that CF initially associates with coated pits at 2 min of incubation at 37 degrees C. With further incubation at 37 degrees C CF is internalized and after 2 to 10 min of incubation is predominantly localized to coated and non-coated clear vesicles. Approximately 50% of the apparent coated vesicles seen near the plasma membrane on single thin sections are shown by serial sectioning to be true vesicles (i.e., without a surface connection). At later time points CF is localized predominantly to lysosomal structures and, to a much smaller extent, Golgi-related structures. The remarkable similarity between 125I-insulin and CF with respect to post-binding processing suggests that while the membrane receptor confers the initial specificity, post-binding events are common for different types of ligands after they bind to cell surfaces and are subject to adsorptive endocytosis.     

Uptake and intracellular routing of peroxidase-conjugated immunoglobulin-G by the perfused human placenta

Summary Selected lobules of term human placenta were extracorporeally perfused and human immunoglobulin-G complexed to horseradish peroxidase (IgG-HRP) was added to the maternal perfusate. After different durations of perfusion IgG-HRP was visualised by use of diamino-benzidine cytochemistry. Within the first 10 min of perfusion IgG-HRP was found bound to microvilli and coated pits of the syncytiotrophoblast; internalisation into coated vesicles and tubulo-vesicular bodies was also observed. Subsequently, IgG-HRP was found in multivesicular bodies and by 30 min appeared in basal vesicles, the frequency of the latter event increasing with time. No routing of IgG-HRP into Golgi regions or lysosomes could be detected. By 60 min IgG-HRP was found in a few caveolae of fetal endothelium of both terminal and intermediate villi. IgG-HRP was not found in intercellular clefts of the endothelium. The pattern of uptake and routing observed suggests a receptor-mediated transcytosis of IgG-HRP across the syncytiotrophoblast and a transcellular pathway through the endothelium.     

Endocytosis via coated pits mediated by glycoprotein receptor in which the cytoplasmic tail is replaced by unrelated sequences.

Rat 6 fibroblast cell lines expressing wild-type chicken liver glycoprotein receptor (CHL) or chimeric receptors with alternate cytoplasmic tails were produced to study the role of the cytoplasmic tail in mediating receptor localization in coated pits and endocytosis of ligand. Cells expressing CHL or cells expressing a hybrid receptor that contains the cytoplasmic tail of the asialoglycoprotein receptor display high-efficiency endocytosis of N-acetylglucosamine-conjugated bovine serum albumin in experiments designed to measure an initial internalization step, as well as in studies of continuous uptake and degradation. Substitution of the cytoplasmic tail by the equivalent domain of rat Na,K-ATPase beta subunit or by a stretch of Xenopus laevis globin beta chain does not abolish endocytosis but decreases the endocytosis rate constant from 15%-16%/min to 2.4% and 6.5%/min, respectively. Electron microscopy was used to visualize the glycoprotein binding sites at the surface of Rat 6 cells transfected with the various receptors. The percentage of receptors found in coated areas ranged from 32% for CHL to 9% for the Na,K-ATPase hybrid, indicating that clustering in coated pits correlates with efficiency of endocytosis. We concluded that replacement of the CHL cytoplasmic tail with unrelated sequences does not prevent, but decreases to varying extents, coated-pit localization and endocytosis efficiency. The construct with NH2-terminal globin tail lacks a signal for high-efficiency localization in coated pits but nevertheless is directed to the pits by an alternative mechanism.     

Receptor-mediated pinocytosis of IgG and immune complex in rat peritoneal macrophages: an electron microscopic study

The uptake mechanism of homologous IgG and immune complex, and the participation of coated vesicles in this process were studied in rat peritoneal macrophages. Peroxidase-antiperoxidase (PAP) immune complex produced in rat, and purified rat IgG adsorbed to gold particles (IgG-Au) were used as ligands. Freshly collected peritoneal macrophages were preincubated with the ligands at 4 degrees C, washed, warmed up to 37 degrees C, maintained in a serum-free culture medium for 5 sec to 30 min and subsequently fixed for electron microscopy. In the IgG-Au experiments, acid phosphatase reaction was also applied to identify lysosomes, and ruthenium red to trace membranes exposed to the extracellular space. At the end of the preincubation period PAP and IgG were found randomly distributed on the external surface of the plasma membrane. After warming up the cells to 37 degrees C, the ligands bound to the plasma membrane showed a tendency to move towards deep labyrinthic invaginations of the cell surface from where they were internalized via coated pits and coated vesicles. In the initial period, these structures seemed to be the primary carriers of the ligands. In the period between 5 and 10 min, ligands were concentrated in vacuoles (endosomes) located in the deeper cytoplasm, while after 30 min, they were present in large lysosome-like or multivesicular bodies, which were found to be acid phosphatase positive.     

A monoclonal antibody to the heavy chain of clathrin.

Monoclonal antibodies have been raised to pig brain triskelions and one clone, DC41, was found to recognize the clathrin heavy chain by immunoblotting. However, both by immunofluorescence and immunoelectron microscopy, and in complete contrast to polyclonal anti-clathrin antibodies, monoclonal DC41 did not label either coated pits or coated vesicles anywhere in the cell. Instead it appeared to label the cell cytoplasm. These data suggest that DC41 recognizes a cytoplasmic form of clathrin, perhaps that form produced by uncoating of coated vesicles which is then ready to re-build another coated pit.     

Colloidal gold-labeled insulin complex. Characterization and binding to adipocytes

Biologically active insulin gold complex was used as an ultrastructural marker to study insulin binding sites, uptake, and internalization in isolated rat adipocytes. The preparation conditions for monodispersed particles, ca. 16 nm in diameter and loaded with approximately 100 insulin molecules, are reported. The complex is stable for at least six weeks. Single particles or small clusters were scattered across the cell membrane. The distribution of unbound receptors seemed to be independent of the extensive system of pre-existing surface connected vesicles in adipocytes. The uptake of particles took place predominantly via non-coated pinocytotic invaginations; clathrin-coated pits did not seem to be important for this process. Lysosome-like structures contained aggregates of 10-15 particles. These data suggest that insulin gold complex is a useful marker for the specific labeling of insulin binding sites.     

Colloidal gold-labeled insulin complex

Summary Biologically active insulin gold complex was used as an ultrastructural marker to study insulin binding sites, uptake, and internalization in isolated rat adipocytes. The preparation conditions for monodispersed particles, ca. 16 nm in diameter and loaded with approximately 100 insulin molecules, are reported. The complex is stable for at least six weeks. Single particles or small clusters were scattered across the cell membrane. The distribution of unbound receptors seemed to be independent of the extensive system of pre-existing surface connected vesicles in adipocytes. The uptake of particles took place predominantly via non-coated pinocytotic invaginations; clathrin-coated pits did not seem to be important for this process. Lysosome-like structures contained aggregates of 10–15 particles. These data suggest that insulin gold complex is a useful marker for the specific labeling of insulin binding sites.Supported by Deutsche Forschungsgemeinschaft D3 SFB 87     

Receptor-mediated endocytosis in cultured fibroblasts: cryptic coated pits and the formation of receptosomes

Concentrative receptor-mediated endocytosis of many specific ligands by cultured fibroblasts occurs through the coated pit-receptosome pathway. The formation of receptosomes was studied using two impermeant electron-dense labels for the cell surface, ruthenium red and concanavalin A-horseradish peroxidase. These studies show that at 4 degrees C, virtually all coated structures near the plasma membrane are in communication with the cell surface, and are not isolated coated vesicles. On warming cells to 37 degrees C for only 1 minute, a major portion of these structures become cryptic, that is, not labeled by these surface markers. However, on cooling cells immediately back to 4 degrees C, virtually all of these structures are again in communication with the surface. Many images showed that membrane of these cryptic pits to be continuous with the cell surface when caught in the appropriate plane of section; often there was a very narrow entrance that excluded extracellular label. At 37 degrees C, receptosomes could be occasionally seen forming as an invagination of membrane adjacent to the coated region. Mechanisms by which receptosomes may form and other evidence demonstrating the failure of coated pits to pinch off to form isolated coated vesicles during endocytosis are discussed.     

Morphological localization of a major lysosomal membrane glycoprotein in the endocytic membrane system

We have raised specific polyclonal immunoglobulin G (IgG) against a major lysosomal membrane sialoglycoprotein (LGP107) taken from rat liver and have prepared a conjugate of its Fab' fragment with horseradish peroxidase (HRP-anti LGP107 Fab') as a probe for the subcellular antigen. Electron immunocytochemistry in primary cultured rat hepatocytes showed that LGP107 resided primarily within lysosomes and was associated with luminal amorphous materials as well as limiting membranes. In addition, LGP107 was shown to be substantially distributed throughout the endocytic vacuolar system. The glycoprotein was found clustered in coated pits at the cell surface and localized along the surrounding membranes in endocytic vesicles. When cultured cells were exposed to HRP-anti LGP107 Fab', the antibody which was bound to its antigen within the coated pits was internalized via a system of endocytic vesicles and transported to lysosomes. During 20 min of incubation at 37 degrees C, the HRP tracer appeared at an early stage in small vesicles and moved progressively to larger vesicles, including multivesicular bodies. After 1 h, the tracer could be clearly seen in lysosomes heterogeneous in shape and size. The existence of LGP107 in endocytic compartments and the uptake of anti LGP107 antibody by hepatocytes were not blocked by prior treatment of the cells with cycloheximide and excess amounts of anti LGP107 IgG. These data suggest that LGP107 circulates between the cell surface and lysosomes through the endocytic membrane traffic in hepatocytes.     

Serial section analysis of coated pits and coated vesicles in soybean protoplasts

Divergent viewpoints have been expressed regarding the existence of free coated vesicles in animal cells; this question has not been carefully addressed with plant tissues. Soybean suspension culture protoplasts were exposed to cationized ferritin (CF) for short times to label coated pits and coated vesicles. A serial section analysis did not reveal deep coated pits with long necks as reported in animal cells. Serial sections clearly demonstrated CF-labelled coated vesicles to be separate organelles and is consistent with the idea that they transfer CF from coated pits to other cytoplasmic organelles during endocytosis.     

alpha 2 Macroglobulin binding to the plasma membrane of cultured fibroblasts. Diffuse binding followed by clustering in coated regions

Using transmission electron microscopy, we have studied the interaction of alpha 2 macroglobulin (alpha 2 M) with the surface of cultured fibroblasts. When cells were incubated for 2 h at 4 degrees C with ferritin-conjugated alpha 2 M, approximately 90% of the alpha 2 M was diffusely distributed on the cell surface, and the other 10% was concentrated in "coated" pits. A pattern of diffuse labeling with some clustering in "coated" pits was also obtained when cells were incubated for 5 min at 4 degrees C with alpha 2 M, fixed with glutaraldehyde, and the alpha 2 M was localized with affinity-purified, peroxidase-labeled antibody to alpha 2 M. Experiments in which cells were fixed with 0.2% paraformaldehyde before incubation with alpha 2 M showed that the native distribution of alpha 2 M receptors was entirely diffuse without significant clustering in "coated" pits. This indicates that some redistribution of the alpha 2 M-receptor complexes into clusters occurred even at 4 degrees C. In experiments with concanavalin A(Con A), we found that some of the Con A clustered in coated regions of the membrane and was internalized in coated vesicles, but much of the Con A was directly internalized in uncoated vesicles or pinosomes. We conclude that unoccupied alpha 2 M receptors are diffusely distributed on the cell surface. When alpha 2 M-receptor complexes are formed, they rapidly cluster in coated regions or pits in the plasma membrane and subsequently are internalized in coated vesicles. Because insulin and epidermal growth factor are internalized in the same structures as alpha 2 M (Maxfield, F.R., J. Schlessinger, Y. Schechter, I. Pastan, and M.C. Willingham. 1978. Cell, 14: 805--810.), we suggest that all peptide hormones, as well as other proteins that enter the cell by receptor-mediated endocytosis, follow this same pathway.     

Endocytotic pathways in the melanotroph of the rat pituitary

Summary The internalization of the extracellular markers horseradish peroxidase (HRP) and cationized ferritin (CF) by the melanotrophs of the intermediate lobe of the rat pituitary was studied during short-time incubation of mechanically dissociated cells or in cell culture after 5 days. After a 30 min exposure, the tracers were found in electron-lucent granules or vacuoles of approximately the same size as the secretory granules, situated 200–500 nm from the cell membrane. In the cultured cells, which showed a higher rate of tracer uptake, internalization was followed for 1, 2 and 5 min after labelling and during 2 h of exposure. Initially, the label was seen only in coated pits and coated vesicles at the cell membrane. Larger vacuoles were first seen after 2–5 min of incubation. After 2 h of exposure the labelling pattern was distinctly different for the two tracers. CF was found in larger vacuoles of varying morphology, in dilatations at the base of cilia, within Golgi saccules and at the edge of the electron-dense core of forming secretory granules. HRP was found in an extensive array of tubulovesicular structures extending throughout the cytoplasm. The Golgi complex and forming granules were, however, not labelled with HRP. The study identifies part of the electron-lucent granules or vacuoles in the melanotroph as endosomes, and shows that the melanotrophs sort CF and HRP via diverting pathways after internalization, suggesting that granule membrane, and possibly its functional components, can be recycled in these cells.     

The intracellular movement and cycling of ricin

The binding, internalization and recycling of the plant toxin ricin, was studied using electron microscopy and biochemical techniques. For the electron microscope study, ricin was visualized using a gold-labeled second antibody, in the cells of the EJ human bladder carcinoma line growing in monolayer culture. The labeled antibody/toxin complex was found to enter the cell in coated pits and to accumulate in endosomes and to a lesser extent in vesicles associated with the Golgi system. The complex recycled to the cell surface partly in uncoated vesicles, but largely in multivesicular bodies which appeared to exocytose their contents to the extracellular space. Twenty hours after the initial contact with ricin as much as 50% of the cellular label was found on the cell surface mainly associated with shed vesicles. When cells were treated with unlabeled ricin holotoxin and then after 20 h stained post-fixation, ricin molecules, partly associated with vesicles, were present on the cell surface. Biochemical studies showed that ricin was internalized by cells and then released in an intact form to the extracellular space. It was found that less than 10% of the released material had been degraded during its passage through the cells, which is in accord with the low level of label found in the lysosomal system during the morphological study.