Inhibition of the discharge of endocytosed protein from phagosomes into lysosomes in hepatoma cells exposed to dimerized ribonuclease A.

The mechanism of the cytostatic action of dimerized ribonuclease A toward cultured hepatoma cells was investigated. A decrease in mitotic index, modifications of adsorptive properties of the pericellular membrane and inhibition of the degradation of two different proteins taken up by endocytosis are the first cell functions to be affected by the dimer. This effect on protein digestion is not due to an inhibition of proteolytic enzymes. The intracellular localization of exogenous protein and of ribonuclease dimer was studied by cell fractionation. When proteins (horseradish peroxidase or rabbit immunoglobulin G) are taken up by control hepatoma cells, they are first associated with phagosomes equilibrating at a lower density than lysosomes; their density distribution gradually becomes similar to that of lysosomes. When cells are pre-exposed to ribonuclease dimer, this modification of the density distribution as a function of time no longer occurs, although these proteins are still intracellular, as indicated by fractionation by differential centrifugation. During the first hour after addition of ribonuclease dimer, kinetic studies show an increased fixation of peroxidase to the cell membrane. Protein release into the culture medium is also increased. These results can be explained either by an absence of fusion between phagosomes and lysosomes, or by an inhibition of the discharge of peroxidase adsorbed to the phagosomal membrane after fusion.     

A comparative study of fluid-phase and adsorptive endocytosis of horseradish peroxidase in lymphoid cells

Adsorptive and fluid-phase endocytosis of horseradish peroxidase (PO) was studied in lymph node cells depleted of macrophages, taken from popliteal lymph nodes of rats immunized against PO (anti-PO cells) and against rabbit IgG (anti-rIgG cells) respectively. The enzymatic activity of PO enabled us to measure the amount of PO endocytosed in the cells and to determine its subcellular localization by means of light and electron microscopy. Uptake of PO by anti-PO cells was a saturable process which reached a plateau at approx. 50 μg/ml of PO. After exposure for 3 h to 50–100 μg/ml of PO, anti-PO cells had endocytosed 5–6 ng of PO per 10⁷ cells. Internalized PO was distributed in cells carrying surface receptors for PO, representing about 6% of the total cell population and consisting mainly of large immunocytes (lymphoblasts, plasma cells). Anti-rIgG cells cultured for 3 h with 100 μ/ml of PO endocytosed a very minute, barely detectable amount of PO. The fluid-phase endocytosis of PO was observed by increasing the PO concentration in the culture medium of anti-rIgG cells. Anti-rIgG cells cultured for 3 h with 500 μg/ml of PO endocytosed about 6 ng of PO/10⁷ cells, but no (or very few) stained cells were found. A large number of PO-internalizing anti-rlgG cells were observed only after culture with high PO concentrations (2 or 5 mg/ml), being both large immunocytes and small-to-medium lymphocytes. Endocytic sites of PO in anti-PO large immunocytes and in anti-rIgG small lymphocytes or large immunocytes were the same and consisted of vesicles, tubules or cisternae located near the Golgi apparatus and round or oval bodies scattered throughout the cytoplasm or localized near the Golgi apparatus (lysosomes?). After exposure to PO, anti-PO and anti-rIgG cells were transferred into PO-free medium. The level of intracellular peroxidase activity did not change during the first 6 h of culture. Then a decrease in enzymatic activity occurred, most probably due to a degradation of PO, at the same rate in anti-PO as in anti-rIgG cells. In conclusion, our results show that intracellular pathways of endocytosis and rates of inactivation of PO entering lymphoid cells are the same, whether specific receptors are present or not. This suggests that endocytosis of antigen in antigen-binding cells could reflect a native membrane recycling event.     

The relationship between autophagy and the intracellular degradation of asialoglycoproteins in cultured rat hepatocytes

The relationship between autophagy and the intracellular distribution of endocytosed asialoorosomucoid was studied in cultured rat hepatocytes. Overt autophagy was induced by shifting the cells to a minimal salt medium. Incubation in minimal salt medium led to the formation of buoyant lysosomes at the expense of denser lysosomes manifested as a dual distribution of these organelles in Nycodenz gradients. Asialoorosomucoid was labeled with 125I-tyramine cellobiose. The labeled degradation products formed from this ligand are trapped at the site of degradation and may therefore serve as markers for the subgroup of lysosomes involved in the degradation. In control cells the degradation of the ligand was initiated in a light prelysosomal compartment and continued in denser lysosomes. In cells with high autophagic activity, the degradation of labeled asialoorosomucoid took place exclusively in a buoyant group of lysosomes. These results suggest that degradation of endocytosed ligand takes place in the same secondary lysosomes as substrate sequestered by autophagic mechanisms. These light lysosomes represent a subgroup of active lysosomes which are gradually recruited from dense bodies. Data are also presented that indicate that insulin may prevent the change in buoyant density brought about by incubation in deficient medium.     

Degradation of transplanted rat liver mitochondrial-outer-membrane proteins in hepatoma cells.

Reductively [3H]methylated 3H mitochondrial-outer-membrane vesicles from rat liver and vesicles where monoamine oxidase has been derivatized irreversibly by [3H]-pargyline have been deliberately miscompartmentalized by heterologous transplantation into hepatoma (HTC) cells by poly(ethylene glycol)-mediated vesicle-cell fusion. Fluorescein-conjugated mitochondrial-outer-membrane vesicles have also been used to show that transplanted material is patched, capped and internalized. Reductively methylated outer-membrane proteins and monoamine oxidase are destroyed at the same rate (t1/2 24 h). Mitochondrial-outer-membrane proteins are not degraded at the same rate as HTC plasma-membrane proteins, endogenous cell protein, or endocytosed protein. Transplanted radiolabelled mitochondrial-outer-membrane proteins accumulate intracellularly in structures that are distinct from plasma membrane and lysosomes. However, when mitochondrial-outer-membrane vesicles derivatized with [14C]sucrose are transplanted, the acid-soluble degradation products accumulate in the lysosomal fraction. [14C]Sucrose-conjugated HTC cell plasma membrane accumulates in intracellular structures that are again distinct from plasma membrane and lysosomes. In contrast with the above observations, homologously transplanted mitochondrial-outer-membrane proteins from rat liver are destroyed in hepatocytes at rates that are remarkably similar (t1/2 60-70 h) to the rates in rat liver in vivo [Evans & Mayer (1982) Biochem. Biophys. Res. Commun. 107, 51-58].     

CYTOCHEMICAL OBSERVATIONS ON THE RELATIONSHIP BETWEEN LYSOSOMES AND PHAGOSOMES IN KIDNEY AND LIVER BY COMBINED STAINING FOR ACID PHOSPHATASE AND INTRAVENOUSLY INJECTED HORSERADISH PEROXIDASE

After incubation of formalin-fixed, frozen sections of kidney and liver from peroxidase-treated rats in an azo dye medium for acid phosphatase, and after subsequent incubation of the same sections with benzidine, phagosomes were stained blue and lysosomes were stained red in the same cells. It was observed that newly formed phagosomes were separate from preexisting lysosomes in the tubule cells of the kidney and in the Kupffer cells of the liver at early periods after treatment with peroxidase. At later periods, the color reactions for acid phosphatase and peroxidase occurred in the same granules. The reaction of peroxidase decreased gradually and disappeared from the phago-lysosomes after 2 to 3 days, whereas the reaction for acid phosphatase persisted. In the liver, most of the injected protein was concentrated in large phagosomes located at the periphery of the cells lining the sinusoids. The peribiliary lysosomes showed a relatively weak reaction for peroxidase in the proximity of the portal veins. After pathological changes of permeability, phagosomes and lysosomes lost their normal location and fused, in the interior of many liver cells, to form large vacuoles or spheres. The effects of a reduced load of peroxidase and the effects of the pretreatment with another protein (egg white) on the phago-lysosomes of the kidney were tested. The relationship of the fusion of phagosomes with lysosomes to the size of normal and pathological phago-lysosomes was discussed.     

A growth hormone-vesicular stomatitis virus G hybrid protein is rapidly degraded in lysosomes following transport to the cell surface

We have expressed the hybrid protein, GHG3, in baby hamster kidney cells to study protein turnover. GHG3 contains the cytoplasmic and transmembrane domains of vesicular stomatitis virus G protein linked to the C-terminus rat growth hormone. Turnover of GHG3 was prevented by lysosomal inhibitors (leupeptin, chloroquine, primaquine or monensin), while the accumulated GHG3 was localized to intracellular vesicles, results indicating that degradation occurred in lysosomes. The kinetics of degradation at 34 degrees C were determined in pulse-chase studies of metabolically labeled cells. After a lag period of 1 h, degradation was rapid (t1/2 = 1.25 h). The fate of GHG3 during the lag period was determined by immunofluorescence. We detected GHG3 on the cell surface when growth hormone antiserum was added to the growth medium 90 min prior to fixation and staining. No staining was observed if protein synthesis was inhibited with cycloheximide 90 min prior to the addition of growth hormone antiserum, a result indicating that GHG3 was rapidly removed from the cell surface. Unless the cells were pretreated with cycloheximide, antiserum was also detected in intracellular vesicles, which showed that GHG3 was endocytosed. These data indicate that a pool of GHG3 is transported rapidly to the cell surface, endocytosed and with little or no recycling directed to lysosomes for degradation.     

Secretion of intact proteins and peptide fragments by lysosomal pathways of protein degradation

We report that degradation of proteins microinjected into human fibroblasts is accompanied by release into the culture medium of peptide fragments and intact proteins as well as single amino acids. For the nine proteins and polypeptides microinjected, acid-precipitable radioactivity, i.e. peptide fragments and/or intact proteins, ranged from 10 to 67% of the total released radioactivity. Peptide fragments and/or intact protein accounted for 60% of the radioactivity released into the medium by cells microinjected with ribonuclease A. Two major radiolabeled peptide fragments were found, and one was of an appropriate size to function as an antigen in antigen-presenting cells. The peptides released from microinjected ribonuclease A were derived from lysosomal pathways of proteolysis based on several lines of evidence. Previous studies have shown that microinjected ribonuclease A is degraded to single amino acids entirely within lysosomes (McElligott, M. A., Miao, P., and Dice, J. F. (1985) J. Biol. Chem. 260, 11986-11993). We show that release of free amino acids and peptide fragments and/or intact protein was equivalently stimulated by serum deprivation and equivalently inhibited by NH4Cl. We also show that lysosomal degradation of endocytosed [3H]ribonuclease A was accompanied by the release of two peptide fragments similar in size and charge to those from microinjected [3H]ribonuclease A. These findings demonstrate that degradation within lysosomes occurs in a manner that spares specific peptides; they also suggest a previously unsuspected pathway by which cells can secrete cytosol-derived polypeptides.     

Endocytosis and chloroquine accumulation during the cell cycle of hepatoma cells in culture

Variations of endocytic and of lysosomal functions during the cell cycle have been investigated in synchronized hepatoma cells (derived from Morris hepatoma 7288c) by following the cellular uptake of horseradish peroxidase, dextran (mol wt. 70,000), and chloroquine. Cell fractionation and cytochemistry show that in asynchronously growing cells exposed for 1 h to 5 mg/ml peroxidase, the bulk of the enzyme taken up by the cells is found in phagosomes. By using the same experimental system with synchronized HTC cells, large variations of endocytosis are observed during the cell cycle. Peroxidase uptake is lowest during mitosis, increases 5--10 times during G1 phase, reaches a plateau, and finally decreases at the end of S phase and during G2 phase. A similar evolution is observed for the uptake of dextran (0.5 or 1 mg/ml), but it is likely that a significant part of the polysaccharide is still associated with the pericellular surface after 1 h. Moreover, dextran is transferred more slowly than peroxidase to lysosomes. Cellular accumulation of chloroquine is related to intralysosomal pH or to the buffering capacity of lysosomes. Our results show that this drug is taken up more rapidly during G1 and S phases while the rate of accumulation is lowest in mitotic cells. The results are discussed in relation to the modifications of the physical properties of lysosomes during the cell cycle observed previously by cell fractionation and electron microsocopy, and to the possible role of lysosomes in the initiation of mitosis. Cyclic changes of endocytosis in actively dividing cells are demonstrated by our observations and may induce large differences in the uptake rate of extracellular substances.     

Cytochemical analysis of organelle degradation in phagosomes and apoptotic cells of the mucoid epithelium of mice.

The activity of mitochondrial cytochrome oxidase and peroxisomal catalase in the phagolysosomes and apoptotic bodies of mucoid epithelial cells was analysed. Tissue from 2-6 day old mice was used. The activity of acid phosphatase in lysosomes was also estimated. Cytochrome oxidase was demonstrated in well-preserved mitochondria inside phagosomes. Mitochondria in cells exhibiting apoptotic death also show activity of cytochrome oxidase. The enzyme activity in swollen mitochondria ceases before the membranes of the cristae disappear completely. Apoptotic bodies are phagocytosed by sister mucoid cells and, later on, they are digested inside the cell. Phagosomes which contain already degraded mitochondria show still active catalase in sequestered peroxisomes. The acid phosphatase involved in degradation of phagocytosed material originates from endocytosed lysosomes and primary and secondary lysosomes which fuse with the membranes of phagosomes.     

Cytochemical analysis of organelle degradation in phagosomes and apoptotic cells of the mucoid epithelium of mice

Summary The activity of mitochondrial cytochrome oxidase and peroxisomal catalase in the phagolysosomes and apoptotic bodies of mucoid epithelial cells was analysed. Tissue from 2–6 day old mice was used. The activity of acid phosphatase in lysosomes was also estimated. Cytochrome oxidase was demonstrated in well-preserved mitochondria inside phagosomes. Mitochondria in cells exhibiting apoptotic death also show activity of cytochrome oxidase. The enzyme activity in swollen mitochondria ceases before the membranes of the cristae disappear completely. Apoptotic bodies are phagocytosed by sister mucoid cells and, later on, they are digested inside the cell. Phagosomes which contain already degraded mitochondria show still active catalase in sequestered peroxisomes. The acid phosphatase involved in degradation of phagocytosed material originates from endocytosed lysosomes and primary and secondary lysosomes which fuse with the membranes of phagosomes.     

Histochemical and ultrastructural observations on digestion in Tetrameres fissispina Diesing, 1861 (Nematoda: Spiruridea) with special reference to intracellular digestion

A large proportion of the blood ingested by Tetrameres fissispina is digested extracellularly to haematin. The probable site of extracellular haemoglobin degradation is the glycocalyx of the microvilli which may carry adsorbed enzymes functional in contact digestion. A smaller proportion of the haemoglobin released from haemolysed erythrocytes is endocytosed in an unchanged state by isolated groups of absorptive cells. In the latter, haemoglobin-containing phagosomes apparently fuse with primary lysosomes ultimately to produce large, heterogeneous, multiple phagolysosomes (digestive complexes). Lipid droplets produced during digestion are extruded from these at intervals. Haemosiderin is the end-product of intracellular haemoglobin breakdown—the differences in residues of the extracellular and intracellular processes (haematin and haemosiderin) reflecting differences in the two enzyme systems employed. Haemosiderin is accumulated as sphaerocrystals in dilated cisternae of the ER. It is suggested that the purpose of intracellular digestion is to provide a source of ferric ions (in the form of haemosiderin) for the biosynthesis of endogenous haemoglobin which the extracellular degradation of haemoglobin cannot supply.     

Intracellular localization and degradation of diphtheria toxin

The internalization of surface-bound diphtheria toxin (DT) in BS-C-1 cells correlated with its appearance in intracellular endosomal vesicles; essentially no toxin appeared within secondary lysosomal vesicles. In contrast, internalized epidermal growth factor (EGF) was localized within both endosomal and lysosomal vesicles. Upon preincubation of cells with leupeptin, a lysosomal protease inhibitor, a threefold increase in the accumulation of EGF into lysosomes was observed. Under identical conditions, essentially all of the diphtheria toxin remained within endosomes (less than 2% of the intracellular diphtheria toxin accumulated in the lysosomal fraction), indicating that the inability to detect diphtheria toxin in lysosomes was not due to its rapid turnover within this vesicle. Following internalization of EGF or DT, up to 40% of the ligand appeared in the medium as TCA-soluble radioactivity. EGF degradation was partially leupeptin-sensitive and markedly NH4Cl-sensitive, indicating lysosomal degradation. In contrast, DT A-fragment degradation was resistant to these inhibitors, while B-fragment showed only partial sensitivity. These data suggest that the bulk of endocytosed diphtheria toxin is localized within endosomes and degraded by a pathway essentially independent of lysosomes.     

Intracellular transport and degradation of chylomicron remnants in rat liver cells after in vivo endocytosis

The intracellular transport and degradation of in vivo endocytosed chylomicron remnants labelled with 125I in the protein moiety was studied in rat liver cells by means of subcellular fractionation in Nycodenz and sucrose density gradients. Initially, the radioactivity was located in low-density endosomes and was sequentially transferred to light and dense lysosomes. Data from gel filtration of the light and dense lysosomal fractions showed radioactive material with a molecular weight of about 1000-2000, representing short peptide fragments or amino acids which remain attached to iodinated tyramine cellobiose. In addition, undegraded apoproteins accumulated in both types of lysosome. Our data suggest that endocytosed chylomicron remnant apoproteins are first located in low-density endosomes and are sequentially transferred to light and dense lysosomes. Furthermore, the degradation process starts in the light lysosomes.     

A coat protein on phagosomes involved in the intracellular survival of mycobacteria.

Mycobacteria are intracellular pathogens that can survive within macrophage phagosomes, thereby evading host defense strategies by largely unknown mechanisms. We have identified a WD repeat host protein that was recruited to and actively retained on phagosomes by living, but not dead, mycobacteria. This protein, termed TACO, represents a component of the phagosome coat that is normally released prior to phagosome fusion with or maturation into lysosomes. In macrophages lacking TACO, mycobacteria were readily transported to lysosomes followed by their degradation. Expression of TACO in nonmacrophages prevented lysosomal delivery of mycobacteria and prolonged their intracellular survival. Active retention of TACO on phagosomes by living mycobacteria thus represents a mechanism preventing cargo delivery to lysosomes, allowing mycobacteria to survive within macrophages.     

Endocytosed non-histone proteins translocate in part to the nucleus in lymphocytes

[3H]Non-histone proteins ([3H]NHP), dissolved in the culture medium, are endocytosed by lymphocytes and equilibrate rapidly between the cytoplasm and the nucleus. During incubation, the proteins are gradually degraded in the lysosomes. The lysosomotropic agents conA, NaF, eserine and atropine have two parallel effects on resting lymphocytes, after they have endocytosed [3H]NHP: inhibition of degradation and increased translocation of [3H]NHP from the cytoplasm to the nucleus. This indicates that lysosomal degradation and translocation of [3H]NHP to the nucleus are linked and suggests that this translocation may be the result of inhibited lysosomal degradation of the [3H]NHP. The behaviour of endocytosed [3H]NHP appears similar to that of endogenous [3H]NHP in cells prelabeled with [3H]leucine, when subjected to the same lysosomotropic agents, reported previously (Polet, H, Exp cell res 148 (1983) 345). This observation may provide a model to study the mechanism(s) controlling nucleo-cytoplasmic traffic of NHP.     

OCCURRENCE OF PHAGOSOMES AND PHAGO-LYSOSOMES IN DIFFERENT SEGMENTS OF THE NEPHRON IN RELATION TO THE REABSORPTION, TRANSPORT, DIGESTION, AND EXTRUSION OF INTRAVENOUSLY INJECTED HORSERADISH PEROXIDASE

The size, number, and location of lysosomes, phagosomes, and phago-lysosomes in different segments of the proximal and distal tubules, in the collecting tubules, and in invading macrophages of the kidneys of rats were compared by staining lysosomes (acid phosphatase) red, and phagosomes (injected horseradish peroxidase) blue in separate sections, and by staining phago-lysosomes purple by successive application of the reactions for the two enzymes in the same sections. It was concluded from these observations that the absorption of the foreign protein from the lumen and its gradual digestion in large phago-lysosomes took place mainly in the cells of the proximal convoluted tubules of the outer cortex. Several segments of the proximal convoluted tubules were distinguished on the basis of differences in the size and location of the phago-lysosomes and the amounts of peroxidase ingested. The distal tubules showed, in addition to moderate numbers of phago-lysosomes, many small phagosomes in the apical and basal zones of the cells. Moderate numbers of phagosomes and phago-lysosomes were observed in the cells of the collecting tubules. Macrophages showing very large phago-lysosomes were seen in the peritubular capillaries of the medulla, after injection of peroxidase. When high doses of peroxidase were administered, enlarged phago-lysosomes, parts of which seemed to be extruded into the lumen, were formed in the terminal segments of the proximal convoluted tubules.     

Uptake and degradation of asialo-fetuin by isolated rat hepatocytes.

125I-labelled asialo-fetuin was taken up by isolated rat hepatocytes by a saturable process. Half maximum uptake was seen at about 3 . 10(-8) M asialo-fetuin. Rate of uptake of asialo-fetuin exceeded rate of degradation at all concentrations of asialo-fetuin tested. Degradation of asialo-fetuin, as indicated by release of acid-soluble radioactivity from the cells, was inhibited by NH4Cl and chloroquine. The intracellular distribution of labelled asialo-fetuin was studied by differential and density gradient centrifuging. The distribution curves for radioactivity indicated that asialo-fetuin was present in lysosomes about 1 h after the uptake had started. Chloroquine and ammonium ions seemed to inhibit the uptake of asialo-fetuin into the lysosomes, possibly by interfering with the fusion between phagosomes and lysosomes.     

Inhibition of functional activity of macrophages in vitro by dimer RNase Bacillus intermedius

The influence of cross-linked by dimethylsuberimidate dimeric RNAse from Bacillus intermedius on peritoneal rat macrophages has been investigated in vitro. It has been shown that dimeric RNase with concentrations of 0.5-40.0 mg/ml decreases the functional activities of macrophages. This is manifested in the inhibition of the phagocyte function of macrophages and suppression of the fusion of phagosomes with lysosomes. The change in the cytoplasmatic membrane surface structure induced by the dimers, which is stronger than that induced by monomers, has been demonstrated using atomic force microscopy. The role of membrane properties modification in the inhibition effect of RNase dimers on the functional activities of macrophages is discussed.     

Binding of concanavalin A to isolated hepatocytes and its effect on uptake and degradation of asialo-fetuin by the cells.

1. The binding of 125I-labelled concanavalin A to isolated rat hepatocytes was studied at temperatures between 4 degrees C and 37 degrees C. At the latter temperature, concentrations of concanavalin A from 0.01 to 0.4 mg/ml were used. In all of these experiments, binding reached a plateau after 40--60 min, when 28--35% of the concanavalin A added was bound to the cells (cell density 8 x 10(6) cells/ml). 2. The rate of uptake of 125I-labelled asialo-fetuin by the hepatocytes was lowered to 30% of control values when the cells were preincubated with 0.1 mg of concanavalin A/ml. This decrease could be accounted for by a decrease in the rate of binding of asialo-fetuin to the beta-galactoside receptor of the cells. The binding capacity of the cells was not influenced by preincubation with concanavalin A. 3. Degradation of asialo-fetuin was decreased only if concanavalin A was present during the uptake of asialo-fetuin by the cells. Subcellular fractionation revealed that concanavalin A lowered the rate of entry of endocytosed asialo-fetuin into the lysosomes. The effect of concanavalin A on degradation is distinct from its effect on the rate of uptake of asialo-fetuin by hepatocytes.     

Glycosylphosphatidylinositol-anchored and core protein-intercalated heparan sulfate proteoglycans in rat ovarian granulosa cells have distinct secretory, endocytotic, and intracellular degradative pathways.

Rat ovarian granulosa cells synthesize two distinct species of plasma membrane-intercalated heparan sulfate (HS) proteoglycans; glycosylphosphatidylinositol (GPI)-anchored and core protein-intercalated HS proteoglycans. Both species of HS proteoglycans are primarily localized on the plasma membrane. Cell surface localization of GPI-anchored and protein-intercalated HS proteoglycans can be determined by their accessibility to exogenously added phosphatidylinositol-specific phospholipase C (PI-PLC) and trypsin, respectively. Kinetic parameters for the processes involving their transfer from the Golgi to the cell surface, endocytosis and secretion, and the modes of intracellular degradation were determined by metabolic labeling experiments using [35S]sulfate and various chase protocols in combination with the use of PI-PLC and trypsin in rat ovarian granulosa cells. The experiments demonstrated that (i) both HS proteoglycan species are transferred from the Golgi to the cell surface with an average transit time of approximately 12 min. (ii) GPI-anchored HS proteoglycans are endocytosed with a t1/2 approximately 3 h, without being shed into the medium, and they are rapidly degraded, t1/2 approximately 25 min, without generating recognizable degradation intermediates. (iii) Protein-intercalated HS proteoglycans are partly (approximately 30%) shed from the cell surface into the medium and the remaining approximately 70% are endocytosed with a t1/2 approximately 4 h. After endocytosis, they undergo a slow (t1/2 approximately 4 h) stepwise degradation generating distinct HS oligosaccharides as degradation intermediates. These results indicate that the GPI-anchored and the protein-intercalated HS proteoglycans have distinct secretory, endocytotic, and intracellular degradation pathways probably due to the differences in their anchor structures.