Cation-independent mannose 6-phosphate and 78 kDa receptors for lysosomal enzyme targeting are located in different cell compartments

The distribution of the cation-independent mannose 6-phosphate and 78 kDa receptors was studied in postnuclear subcellular fractions from two rat liver cell lines. ELISA assays revealed that the mannose 6-phosphate receptor is enriched in the light buoyant Percoll fractions that contain Golgi structures and early endosomes. Most of the 78 kDa receptor is localized in a heavy fraction at the bottom of the Percoll gradient and smaller amounts in the endosomal fractions. The high-density compartment is denser than lysosomes, contains LAMP2 but not LIMPII or acid hydrolases, and is not disrupted with glycyl-l-phenylalanine 2-naphthylamide, a substrate for cathepsin C that selectively disrupts lysosomes. Immunofluorescence microscopy studies indicate no colocalization of the 78 kDa receptor with the mannose 6-phosphate receptor or LIMPII. Mannose 6-phosphate-independent endocytosed beta-glucuronidase was found in the lysosomal, the early and late endosomal fractions. These fractions were immunoadsorbed in columns containing antibodies against the 78 kDa receptor. Only the endocytosed beta-glucuronidase present in the early and late endosomal fractions is associated to immunoadsorbed vesicles. In these vesicles, LAMP2 was detected but no LIMPII or the mannose 6-phosphate receptor. Results obtained suggest that the 78 kDa receptor is found along the endocytic pathway, but in vesicles different from the cation-independent mannose 6-phosphate receptor.     

Occurrence of an anomalous endocytic compartment in fibroblasts from Sandhoff disease patients

Sandhoff disease (SD) is a lysosomal storage disorder due to mutations in the gene encoding for the β-subunit of β-hexosaminidase, that result in β-hexosaminidase A (αβ) and β-hexosaminidase B (ββ) deficiency. This leads to the storage of GM2 ganglioside in endosomes and lysosomes, which ends in a progressive neurodegeneration. Currently, very little is known about the biochemical pathways leading from GM2 ganglioside accumulation to pathogenesis. Defects in transport and sorting by the endosomal–lysosomal system have been described for several lysosomal storage disorders. Here, we have investigated the endosomal–lysosomal compartment in fibroblasts from SD patients and observed that both late endosomes and lysosomes, but not early endosomes, have a higher density in comparison with normal fibroblasts. Moreover, Sandhoff fibroblasts have an intracellular distribution of terminal endocytic organelles that differs from the characteristic perinuclear punctate pattern observed in normal fibroblasts and endocytic vesicles also appear larger. These findings reveal the occurrence of an alteration in the terminal endocytic organelles of Sandhoff fibroblasts, suggesting an involvement of this compartment in the disruption of cell metabolic and signalling pathways and in the onset of the pathological state.     

Effect of ammonium chloride on subcellular distribution of lysosomal enzymes in human fibroblasts

Three subcellular fractions enriched in lysosomal enzyme activities have been isolated recently from human cultured fibroblasts with Percoll gradients: the dense lysosomes (DL), light lysosomes (LL), and light membranous vesicles (LM). They were shown to have different morphological, cytochemical, biochemical, and immunological properties. We now report on the dramatic but different effects of a primary amine, NH4Cl, on these subfractions. The lysosomes, as detected with a specific ultrastructural cytochemical stain for the lysosomal enzyme, arylsulfatase A, were swollen significantly in all these fractions, increasing their volumes by 64% (DL), 53% (LL), and 95% (LM), respectively. When arylsulfatase A enzyme activity was monitored, about half of the DL content was diverted to the LL. However, when newly synthesized arylsulfatase A enzyme protein was monitored with metabolic labeling and immunoprecipitation, about 80% of the enzyme protein was depleted from both the DL and LL. In contrast, neither the enzyme activity nor the newly synthesized enzyme protein of arylsulfatase A was greatly altered in the LM fraction by the treatment. Since primary amines caused newly synthesized lysosomal enzymes to diverge from the lysosomal route to a secretory pathway, it was deduced that (i) the LM fraction corresponded to a prelysosomal compartment whose lysosomal enzyme content was not affected by the amine and was thus proximal to the point of diversion between the secretory and lysosomal pathways; (ii) the LL and DL fractions were distal to the point of diversion since both fractions were depleted of their newly synthesized lysosomal enzyme; and (iii) the sorting of newly synthesized lysosomal enzyme may be different from that of the preexisting pool of the same enzyme since the LL fraction was depleted of its newly synthesized enzyme protein while accumulating excessive enzyme activity.     

Reconstitution of vesicle fusions occurring in endocytosis with a cell-free system.

We have used defined subcellular fractions to reconstitute in a cell-free system vesicle fusions occurring in the endocytic pathway. The endosomal fractions were prepared by immuno-isolation using as antigen an epitope located on a foreign protein, the transmembrane glycoprotein G (G-protein) of vesicular stomatitis virus. The G-protein was first implanted in the cell plasma membrane and subsequently endocytosed for 15 to 30 min at 37 degrees C. The endosomal fractions were immuno-isolated on a solid support using as antigen the cytoplasmic domain of the G-protein in combination with a specific monoclonal antibody. For comparative studies the plasma membrane was immuno-isolated from cells in the absence of G internalization with a monoclonal antibody against the exoplasmic domain of the G-protein. The immuno-isolated endosomal vesicles contained 70% of horseradish peroxidase internalized in the endosome fluid phase, exhibited an acidic luminal pH as shown by acridine orange fluorescence and differed in their protein composition from the immuno-isolated plasma membrane fraction. The fusion of endocytic vesicles originating from different stages of the pathway was studied in a cell-free assay using both a bio-chemical and a morphological detection system. These well defined endosomal vesicles were immuno-isolated with the G-protein on the solid support and provided the recipient compartment of the fusion (acceptor). They were mixed with a post-nuclear supernatant containing endosomes loaded with exogenous lactoperoxidase (donor) at 37 degrees C. Fusion delivered the donor peroxidase to the lumen of acceptor vesicles permitting fusion-specific iodination of the G-protein itself. The fusion of vesicles required ATP and was detected only with an endosomal fraction prepared after internalization of the G-protein for 15 min at 37 degrees C but not with a plasma membrane or with an endosomal fraction prepared after 30 min G-protein internalization.     

Heterogeneity of lysosomes in human fibroblasts

Summary Lysosomes are defined traditionally with the marker enzyme acid phosphatase. We showed recently that lysosomes from human fibroblasts can be separated into a light and dense fraction as well as prelysosomal population. We now provide evidence that although acid phosphatase is enriched in all three fractions, the marker enzyme in the prelysosomal compartment is qualitatively distinct from that of the lysosomes. Ultrastructural analysis showed that the acid phosphatase in the prelysosomal vesicles deposited an extremely electron-dense reaction product, entirely obliterating the lumen of the vesicle, in contrast to that of the light and dense lysosomes which deposited a fine and diffuse product scattered throughout the luminal space. Biochemical analysis showed that only 51% of the acid phosphatase in the prelysosomes was inhibited by tartrate, while 80% of that in the lysosomes was tartrate-inhibitable. Immunoprecipitation with antibodies specific for various isozymes of acid phosphatase showed that 39% of the acid phosphatase in the prelysosomes was of the lysosomal type whereas over 5007o of the acid phosphatase in the lysosomes was of this type. These results showed that acid phosphatase in the prelysosomes of human cultured fibroblasts can be distinguished from that of the lysosomes cytochemically, biochemically, and immunologically and that lysosomes, as marked by acid phosphatase, are a heterogeneous organelle.     

Chinese hamster ovary cell lysosomes retain pinocytized horseradish peroxidase and in situ-radioiodinated proteins.

We used Chinese hamster ovary cells, a cell line of fibroblastic origin, to investigate whether lysosomes are an exocytic compartment. To label lysosomal contents, Chinese hamster ovary cells were incubated with the solute marker horseradish peroxidase. After an 18-h uptake period, horseradish peroxidase was found in lysosomes by cell fractionation in Percoll gradients and by electron microscope cytochemistry. Over a 24-h period, lysosomal horseradish peroxidase was quantitatively retained by Chinese hamster ovary cells and inactivated with a t 1/2 of 6 to 8 h. Lysosomes were radioiodinated in situ by soluble lactoperoxidase internalized over an 18-h uptake period. About 70% of the radioiodine incorporation was pelleted at 100,000 X g under conditions in which greater than 80% of the lysosomal marker enzyme beta-hexosaminidase was released into the supernatant. By one-dimensional electrophoresis, about 18 protein species were present in the lysosomal membrane fraction, with radioiodine incorporation being most pronounced into species of 70,000 to 75,000 daltons. After a 30-min or 2-h chase at 37 degrees C, radioiodine that was incorporated into lysosomal membranes and contents was retained in lysosomes. These observations indicate that lysosomes labeled by fluid-phase pinocytosis are a terminal component of endocytic pathways in fibroblasts.     

Identification of a membrane glycoprotein found primarily in the prelysosomal endosome compartment

Cells contain an intracellular compartment that serves as both the "prelysosomal" delivery site for newly synthesized lysosomal enzymes by the mannose 6-phosphate (Man6P) receptor and as a station along the endocytic pathway to lysosomes. We have obtained mAbs to a approximately 57-kD membrane glycoprotein, (called here plgp57), found predominantly in this prelysosomal endosome compartment. This conclusion is supported by the following results: (a) plgp57 was primarily found in a population of late endosomes that were located just distal to the 20 degrees C block site in the endocytic pathway to lysosomes (approximately 83% of the prelysosomes were positive for plgp57 but less than 5% of the early endosomes had detectable amounts of this marker); (b) plgp57 and the cation-independent (CI) Man6P receptor were located in many of the same intracellular vesicles; (c) plgp57 was found in the membranes of an acidic compartment; (d) immunoelectron microscopy showed that plgp57 was located in characteristic multilamellar- and multivesicular-type vacuoles believed to be prelysosomal endosomes; and (e) cell fractionation studies demonstrated that plgp57 was predominantly found in low density organelles which comigrated with late endosomes and CI Man6P receptors, and only approximately 10-15% of the antigen was found in high density fractions containing the majority of secondary lysosomes. These results indicate that plgp57 is a novel marker for a unique prelysosomal endosome compartment that is the site of confluence of the endocytic and biosynthetic pathways to lysosomes.     

Lysosomes can fuse with a late endosomal compartment in a cell-free system from rat liver

The passage of pulse doses of asialoglycoproteins through the endosomal compartments of rat liver hepatocytes was studied by subcellular fractionation and EM. The kinetics of disappearance of radiolabeled asialofetuin from light endosomes prepared on Ficoll gradients were the same as the kinetics of disappearance of asialoorosomucoid-horse radish peroxidase reaction products from intracellular membrane-bound structures in the blood sinusoidal regions of hepatocytes. The light endosomes were therefore identifiable as being derived from the peripheral early endosome compartment. In contrast, the labeling of dense endosomes from the middle of the Ficoll gradient correlated with EM showing large numbers of reaction product-containing structures in the nonsinusoidal parts of the hepatocyte. In cell-free, postmitochondrial supernatants, we have previously observed that dense endosomes, but not light endosomes, interact with lysosomes. Cell-free interaction between isolated dense endosomes and lysosomes has now been reconstituted and analyzed in three ways: by transfer of radiolabeled ligand from endosomal to lysosomal densities, by a fluorescence dequenching assay which can indicate membrane fusion, and by measurement of content mixing. Maximum transfer of radiolabel to lysosomal densities required ATP and GTP plus cytosolic components, including N-ethylmaleimide-sensitive factor(s). Dense endosomes incubated in the absence of added lysosomes did not mature into vesicles of lysosomal density. Content mixing, and hence fusion, between endosomes and lysosomes was maximal in the presence of cytosol and ATP and also showed inhibition by N-ethyl-maleimide. Thus, we have demonstrated that a fusion step is involved in the transfer of radiolabeled ligand from an isolated endosome fraction derived from the nonsinusoidal regions of the hepatocyte to preexisting lysosomes in a cell-free system.     

Distribution and structure of the vacuolar H+ ATPase in endosomes and lysosomes from LLC-PK1 cells

Vacuolar proton pumps acidify several intracellular membrane compartments in the endocytic pathway. We have examined the distribution of the vacuolar H+ ATPase in LLC-PK1 cells and the structure of the biosynthetically labeled enzyme in membrane fractions enriched for endosomes or lysosomes. LLC-PK1 cells were allowed to internalize cytochrome c-coated colloidal gold as a marker for endocytic compartments. Proton pumps were identified in these cells by staining the cells with a monoclonal antibody against the vacuolar pump detected with either immunogold or immunoperoxidase techniques. H+ ATPase labeling was seen on structures resembling endosomes and lysosomes, but not on Golgi or plasma membrane. To examine the structure of the H+ ATPase in these compartments, we labeled LLC-PK1 cells for 24 h with [35S]methionine and used a Percoll gradient to obtain fractions enriched for endosomes or lysosomes. H+ ATPase immunoprecipitated from both fractions with monoclonal anti-H+ ATPase antibodies had labeled polypeptides of 70, 56, and 31 kDa. On two-dimensional gels, a comparison of the H+ ATPase from the endosomal and lysosomal fractions revealed that the 70-, 56-, and 31-kDa subunits were similar in both fractions. The results show that the vacuolar H+ ATPase in these cells is distributed primarily in endosomes and lysosomes and that the structure of the enzyme is similar in both compartments.     

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.     

ARF6 Targets Recycling Vesicles to the Plasma Membrane: Insights from an Ultrastructural Investigation

We have shown previously that the ADP- ribosylation factor (ARF)-6 GTPase localizes to the plasma membrane and intracellular endosomal compartments. Expression of ARF6 mutants perturbs endosomal trafficking and the morphology of the peripheral membrane system. However, another study on the distribution of ARF6 in subcellular fractions of Chinese hamster ovary (CHO) cells suggested that ARF6 did not localize to endosomes labeled after 10 min of horseradish peroxidase (HRP) uptake, but instead was uniquely localized to the plasma membrane, and that its reported endosomal localization may have been a result of overexpression. Here we demonstrate that at the lowest detectable levels of protein expression by cryoimmunogold electron microscopy, ARF6 localized predominantly to an intracellular compartment at the pericentriolar region of the cell. The ARF6-labeled vesicles were partially accessible to HRP only on prolonged exposure to the endocytic tracer but did not localize to early endocytic structures that labeled with HRP shortly after uptake. Furthermore, we have shown that the ARF6-containing intracellular compartment partially colocalized with transferrin receptors and cellubrevin and morphologically resembled the recycling endocytic compartment previously described in CHO cells. HRP labeling in cells expressing ARF6(Q67L), a GTP-bound mutant of ARF6, was restricted to small peripheral vesicles, whereas the mutant protein was enriched on plasma membrane invaginations. On the other hand, expression of ARF6(T27N), a mutant of ARF6 defective in GDP binding, resulted in an accumulation of perinuclear ARF6-positive vesicles that partially colocalized with HRP on prolonged exposure to the tracer. Taken together, our findings suggest that ARF activation is required for the targeted delivery of ARF6-positive, recycling endosomal vesicles to the plasma membrane.     

Distinct protein sorting and localization to premelanosomes, melanosomes, and lysosomes in pigmented melanocytic cells

Melanosomes and premelanosomes are lysosome-related organelles with a unique structure and cohort of resident proteins. We have positioned these organelles relative to endosomes and lysosomes in pigmented melanoma cells and melanocytes. Melanosome resident proteins Pmel17 and TRP1 localized to separate vesicular structures that were distinct from those enriched in lysosomal proteins. In immunogold-labeled ultrathin cryosections, Pmel17 was most enriched along the intralumenal striations of premelanosomes. Increased pigmentation was accompanied by a decrease in Pmel17 and by an increase in TRP1 in the limiting membrane. Both proteins were largely excluded from lysosomal compartments enriched in LAMP1 and cathepsin D. By kinetic analysis of fluid phase uptake and immunogold labeling, premelanosomal proteins segregated from endocytic markers within an unusual endosomal compartment. This compartment contained Pmel17, was accessed by BSA-gold after 15 min, was acidic, and displayed a cytoplasmic planar coat that contained clathrin. Our results indicate that premelanosomes and melanosomes represent a distinct lineage of organelles, separable from conventional endosomes and lysosomes within pigmented cells. Furthermore, they implicate an unusual clathrin-coated endosomal compartment as a site from which proteins destined for premelanosomes and lysosomes are sorted.     

Sterol-modulated glycolipid sorting occurs in niemann-pick C1 late endosomes

The Niemann-Pick C1 (NPC1) protein and endocytosed low density lipoprotein (LDL)-derived cholesterol were shown to enrich separate subsets of vesicles containing lysosomal associated membrane protein 2. Localization of Rab7 in the NPC1-containing vesicles and enrichment of lysosomal hydrolases in the cholesterol-containing vesicles confirmed that these organelles were late endosomes and lysosomes, respectively. Lysobisphosphatidic acid, a lipid marker of the late endosomal pathway, was found in the cholesterol-enriched lysosomes. Recruitment of NPC1 to Rab7 compartments was stimulated by cellular uptake of cholesterol. The NPC1 compartment was shown to be enriched in glycolipids, and internalization of GalNAcbeta1-4[NeuAcalpha2-3]Galbeta1-4Glcbeta1-1'-ceramide (G(M2)) into endocytic vesicles depends on the presence of NPC1 protein. The glycolipid profiles of the NPC1 compartment could be modulated by LDL uptake and accumulation of lysosomal cholesterol. Expression in cells of biologically active NPC1 protein fused to green fluorescent protein revealed rapidly moving and flexible tubular extensions emanating from the NPC1-containing vesicles. We conclude that the NPC1 compartment is a dynamic, sterol-modulated sorting organelle involved in the trafficking of plasma membrane-derived glycolipids as well as plasma membrane and endocytosed LDL cholesterol.     

Distribution and structure of the vacuolar H ATPase in endosomes and lysosomes from LLC-PK1, cells

Vacuolar proton pumps acidify several intracellular membrane compartments in the endocytic pathway. We have examined the distribution of the vacuolar H⁺ ATPase in LLC-PK₁ cells and the structure of the biosynthetically labeled enzyme in membrane fractions enriched for endosomes or lysosomes. LLC-PK₁ cells were allowed to internalize cytochrome c-coated colloidal gold as a marker for endocytic compartments. Proton pumps were identified in these cells by staining the cells with a monoclonal antibody against the vacuolar pump detected with either immunogold or immunoperoxidase techniques. H⁺ ATPase labeling was seen on structures resembling endosomes and lysosomes, but not on Golgi or plasma membrane. To examine the structure of the H⁺ ATPase in these compartments, we labeled LLCPK₁ cells for 24 h with [³⁵S]methionine and used a Percoll gradient to obtain fractions enriched for endosomes or lysosomes. H⁺ ATPase immunoprecipitated from both fractions with monoclonal anti-H⁺ ATPase antibodies had labeled polypeptides of 70, 56, and 31 kDa. On two-dimensional gels, a comparison of the H⁺ ATPase from the endosomal and lysosomal fractions revealed that the 70-, 56-, and 31-kDa subunits were similar in both fractions. The results show that the vacuolar H⁺ ATPase in these cells is distributed primarily in endosomes and lysosomes and that the structure of the enzyme is similar in both compartments.     

Purification and characterization of lysosomes from Chinese hamster ovary cells

Lysosomes were isolated from Chinese hamster ovary cells by fractionation of a postnuclear supernatant in consecutive density gradients. By marker enzyme analysis, the preparation was 63-fold enriched for lysosomes compared to the homogenate and contained at most trace amounts of marker activities for plasma membrane, Golgi, endoplasmic reticulum, peroxisomes, cytosol, and mitochondria. The lysosomes were intact as indicated by greater than 95% latency of beta-hexosaminidase activity, and the yield was about 12% relative to the homogenate. By electron microscopy, the lysosomal preparation contained very few mitochondrial profiles. By cytochemistry, greater than 80% of the organelle profiles were positive for the native lysosomal marker, acid phosphatase, and profiles were positive for long-term internalized horseradish peroxidase, an endocytic marker for lysosomes. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the lysosomal preparation displayed a unique pattern of polypeptides and was devoid of mitochondrial contamination. Lysosomes were fractionated into membrane and lumenal compartments by Na2CO3 treatment. Each compartment contained 20-30 distinct electrophoretic species ranging from 18 to 200 kDa. Each polypeptide could be assigned to either the membrane or lumenal compartment. A comparison of silver-stained polypeptides with those metabolically labeled with [35S]methionine indicated that, with the possible exception of an 18-kDa species, all of the major lysosomal polypeptides in both compartments were derived by endogenous synthesis in these exponentially growing fibroblasts.     

Ile (476), a constituent of di-leucine-based motif of a major lysosomal membrane protein,LGP85/LIMP II,is important for its proper distribution in late endosomes and lysosomes

Lysosomal membrane glycoprotein termed LGP85 or LIMP II extends a COOH-terminal cytoplasmic tail of R459GQGSMDEGTADERAPLIRT478, in which an L475 I476 sequence lies as a di-leucine-based motif for lysosomal targeting. In the present study, we explored the role of the I476 residue in the localization of LGP85 to the endocytic organelles using two substitution mutants called I476A and I476L in which alanine and leucine are replaced at I476, respectively, and I476R477T478-deleted LGP85 called Delta 476-478. Immunofluorescence analyses showed that I476A and I476L are largely colocalized in intracellular organelles with an endogenous late endosomal and lysosomal marker, LAMP-1, but there were some granules in which staining for the LGP85 mutants was prominent, while Delta 476-478 is detected in LAMP-1-positive and LAMP-1-negative intracellular organelles, and on the cell surface. The subcellular fractionation studies revealed that I476A, I476L, and Delta 476-478 are different from wild-type LGP85 in the distribution of early endosomes, late endosomes, and lysosomes. I476A and I476L are present more in late endosomes than in the densest lysosomes, whereas wild-type LGP85 is mainly lysosomal. Substitution of I476 for A and L differentially modified the ratios of late endosomal to lysosomal LGP85. A major portion of Delta 476-478 resided in the light buoyant density fraction containing plasma membrane and early endosomes. Taken together, these results indicate that the existence of the 476th amino acid residue is essential for localization of LGP85 to late endocytic compartments. The fact that isoleucine but not leucine is in the 476th position is especially of importance in the proper distribution of LGP85 in late endosomes and lysosomes.     

A quantitative analysis of the endocytic pathway in baby hamster kidney cells

A morphological analysis of the compartments of the endocytic pathway in baby hamster kidney (BHK) cells has been made using the fluid-phase marker horseradish peroxidase (HRP). The endocytic structures labeled after increasing times of endocytosis have been identified and their volume and surface densities measured. In the first 2 min of HRP uptake the volume density of the labeled structures increased rapidly and thereafter remained constant for the next 13-18 min. This plateau represents the volume density of endosome organelles and accounts for 0.65% of the cytoplasmic volume (or 6.8 microns 3 per cell). The labeled structures consist of tubular-cisternal elements which are frequently observed in continuity with 300-400 nm vesicles. After 15-20 min of internalization the volume density of HRP-labeled structures again increased rapidly and reached a second plateau between 30 and 60 min of labeling. This second increase corresponded to detectable levels of HRP reaching later, acid phosphatase (AcPase)-reactive compartments. These structures, comprising the prelysosomes and lysosomes, were mostly vesicular and collectively accounted for 3.5% of the cytoplasmic volume (or 37 microns 3 per cell). The absolute peripheral surface areas of the two classes of organelles (endosomes and prelysosomes/lysosomes) were estimated to be 430 and 370 microns 2 per cell, respectively. The volume of fluid internalized in the first 2 min of uptake was five- to sevenfold less than the volume of the compartment labeled in this time. To account for these results we propose that, after uptake from the cell surface, HRP is delivered to, and diluted in, endosomes that are preexisting organelles initially devoid of the marker. With increasing times of endocytosis the concentration of HRP in the early endosomes increases, as more of the marker enters this compartment. An elevation in HRP concentration in endosomes during the early time points was shown directly using anti- HRP antibodies and colloidal gold on cryosections. The stereological values given in the present study, in combination with earlier studies, provide a minimum estimate for both the total surface area of membranes and the rate of membrane synthesis in a BHK cell.     

Effect of monensin on the neuronal ultrastructure and endocytic pathway of macromolecules in cultured brain neurons

1. The endocytic pathway of horseradish peroxidase (HRP) was investigated in the perikarya of cultured neurons by electron microscopy and enzyme cytochemistry. The tracer was observed in endocytic pits and vesicles, endosomes, multivesicular bodies, and lysosomes. It took approximate 15 min for the transfer of HRP from the exterior of the cell to the lysosomes. 2. Monensin induced distension of the Golgi apparatus and formation of intracellular vacuoles. When neurons were incubated with both monensin and HRP for 30 to 120 min, the number of HRP-labeled endosomes was greater than that in the monensin-free group, whereas the reverse was seen for HRP-positive lysosomes. The formation of HRP-positive lysosomes in monensin-treated cells was blocked by 47 to 79%. 3. These results indicate that the intracellular transport of the endocytosed macromolecule is pH dependent. It is also possible that the export of lysosomal enzymes is inhibited by monensin, resulting in an accumulation of the endosomes and a reduction of the lysosomes.     

Endocytic vesicles from renal papilla which retrieve the vasopressin- sensitive water channel do not contain a functional H+ ATPase

The water permeability of the kidney collecting duct epithelium is regulated by vasopressin (VP)-induced recycling of water channels between an intracellular vesicular compartment and the plasma membrane of principal cells. To test whether the water channels pass through an acidic endosomal compartment during the endocytic portion of this pathway, we measured ATP-dependent acidification of FITC-dextran-labeled endosomes in isolated microsomal fractions from different regions of Brattleboro rat kidneys. Both VP-deficient controls and rat treated with exogenous VP were examined. ATP-dependent acidification was not detectable in endosomes containing water channels from distal papilla (osmotic water permeability Pf = 0.038 +/- 0.004 cm/s). In contrast, the addition of ATP resulted in a strong acidification of renal cortical endosomes (pHmin = 5.8, initial rate = 0.18-0.25 pH U/s). Acidification of cortical endosomes was reversed with nigericin and strongly inhibited by N-ethyl-maleimide. Passive proton permeability was similar and low in both cortical and papillary endosomes from rats treated or not treated with VP. The fraction of labeled endosomes present in microsomal preparations was determined by fluorescence imaging microscopy of microsomes nonspecifically bound to poly-l-lysine-coated coverslips and was 25% in cortical preparations compared to 14% (+VP) and 9% (-VP) in papillary preparations. The fraction of cortical endosomes was enriched 1.5-fold by immunoabsorption to coverslips coated with mAbs against the bovine vacuolar proton pump. In contrast, the fraction of papillary endosomes was depleted more than twofold by immunoabsorption to identical coverslips. Finally, sections of distal papilla stained with antibodies against the lysosomal glycoprotein LGP120 showed that most of the entrapped FITC-dextran did not colocalize with this lysosomal protein. These results demonstrate that vesicles which internalize water channels in kidney collecting duct principal cells lack functional proton pumps, and do not deliver the bulk of their FITC-dextran content to lysosomes. The data suggest that the principal cell contains a specialized nonacidic apical endocytic compartment which functions primarily to recycle membrane components, including water channels, to the plasma membrane.     

Accumulation of sialic acid in endocytic compartments interferes with the formation of mature lysosomes. Impaired proteolytic processing of cathepsin B in fibroblasts of patients with lysosomal sialic acid storage disease.

The impact of an altered endocytic environment on the biogenesis of lysosomes was studied in fibroblasts of patients suffering from sialic acid storage disease (SASD). This inherited disorder is characterized by the accumulation of acidic monosaccharides in lysosomal compartments and a concomitant decrease of their buoyant density. We demonstrate that C-terminal trimming of the lysosomal cysteine proteinase cathepsin B is inhibited in SASD fibroblasts. This late event in the biosynthesis of cathepsin B normally takes place in mature lysosomes, suggesting an impaired biogenesis of these organelles in SASD cells. When normal fibroblasts are loaded with sucrose, which inhibits transport from late endosomes to lysosomes, C-terminal cathepsin B processing is prevented to the same extent. Further characterization of the terminal endocytic compartments of SASD cells revealed properties usually associated with late endosomes/prelysosomes. In addition to a decreased buoyant density, SASD "lysosomes" show a reduced acidification capacity and appear smaller than their normal counterparts. We conclude that the accumulation of small non-diffusible compounds within endocytic compartments interferes with the formation of mature lysosomes and that the acidic environment of the latter organelles is a prerequisite for C-terminal processing of lysosomal hydrolases.