Hypertonic sucrose inhibition of endocytic transport suggests multiple early endocytic compartments

Incubation of animal cells with hypertonic sucrose and polyethylene glycol (PEG) 1,000 renders endosomes sensitive in situ to hypotonic shock (Okada and Rechsteiner, 1982). We found that: 1) in vitro endosomes were osmotically insensitive; and 2) hypertonic sucrose inhibited transport from very early endosomes to lysosomes. Endocytic vesicles were labeled by incubating Chinese hamster ovary (CHO) cells for 1-10 min at 37 degrees C with horseradish peroxidase (HRP) and/or fluorescein isothiocyanate-conjugated dextran (FITC-dextran). Cell fractions prepared in 0.25 M sucrose were hypotonically shocked by dilution with 5 mM Na phosphate buffer, pH 6.7, to a final sucrose concentration of 0.05 M. After hypotonic shock, endocytized HRP and FITC-dextran pelleted with membrane while lysosomal hydrolases did not. The HRP activity in the pellet was latent, suggesting that endosomes were resistant to osmotic shock. Uptake in the presence of hypertonic sucrose had little effect on the subsequent osmotic sensitivity of the endosomes. Uptake in the presence of hypertonic sucrose and PEG 1,000 rendered endosomes fragile to cell homogenization. Unexpectedly, the inclusion of hypertonic sucrose in the uptake and chase media inhibited the appearance of HRP in lysosomes. HRP internalized during a 10-min uptake appeared as if it were present in two physically distinct compartments, one accessible to transport inhibition by exogenous sucrose ("very early" endosomes) and the other not ("early" endosomes). After a brief uptake (1-3 min), postincubation of CHO cells in 0.25 M sucrose-containing media completely blocked transport of internalized HRP to lysosomes. This blockage could be partially relieved by cointernalization of invertase with HRP. These results suggest that transport between multiple early endosome populations is sensitive to intraorganellar osmotic conditions.     

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.     

Transport from late endosomes to lysosomes, but not sorting of integral membrane proteins in endosomes, depends on the vacuolar proton pump

Endocytosed proteins are sorted in early endosomes to be recycled to the plasma membrane or transported further into the degradative pathway. We studied the role of endosomes acidification on the endocytic trafficking of the transferrin receptor (TfR) as a representative for the recycling pathway, the cation-dependent mannose 6-phosphate receptor (MPR) as a prototype for transport to late endosomes, and fluid-phase endocytosed HRP as a marker for transport to lysosomes. Toward this purpose, bafilomycin A1 (Baf), a specific inhibitor of the vacuolar proton pump, was used to inhibit acidification of the vacuolar system. Microspectrofluorometric measurement of the pH of fluorescein-rhodamine-conjugated transferrin (Tf)-containing endocytic compartments in living cells revealed elevated endosomal pH values (pH > 7.0) within 2 min after addition of Baf. Although recycling of endocytosed Tf to the plasma membrane continued in the presence of Baf, recycled Tf did not dissociate from its receptor, indicating failure of Fe3+ release due to a neutral endosomal pH. In the presence of Baf, the rates of internalization and recycling of Tf were reduced by a factor of 1.40 +/- 0.08 and 1.57 +/- 0.25, respectively. Consequently, little if any in TfR expression at the cell surface was measured during Baf treatment. Sorting between endocytosed TfR and MPR was analyzed by the HRP-catalyzed 3,3'- diaminobenzidine cross-linking technique, using transferrin conjugated to HRP to label the endocytic pathway of the TfR. In the absence of Baf, endocytosed surface 125I-labeled MPR was sorted from the TfR pathway starting at 10 min after uptake, reaching a plateau of 40% after 45 min. In the presence of Baf, sorting was initiated after 20 min of uptake, reaching approximately 40% after 60 min. Transport of fluid-phase endocytosed HRP to late endosomes and lysosomes was measured using cell fractionation and immunogold electron microscopy. Baf did not interfere with transport of HRP to MPR-labeled late endosomes, but nearly completely abrogated transport to cathepsin D- labeled lysosomes. From these results, we conclude that trafficking through early and late endosomes, but not to lysosomes, continued upon inactivation of the vacuolar proton pump.     

Syntaxin 7 and VAMP-7 are soluble N-ethylmaleimide-sensitive factor attachment protein receptors required for late endosome-lysosome and homotypic lysosome fusion in alveolar macrophages

Endocytosis in alveolar macrophages can be reversibly inhibited, permitting the isolation of endocytic vesicles at defined stages of maturation. Using an in vitro fusion assay, we determined that each isolated endosome population was capable of homotypic fusion. All vesicle populations were also capable of heterotypic fusion in a temporally specific manner; early endosomes, isolated 4 min after internalization, could fuse with endosomes isolated 8 min after internalization but not with 12-min endosomes or lysosomes. Lysosomes fuse with 12-min endosomes but not with earlier endosomes. Using homogenous populations of endosomes, we have identified Syntaxin 7 as a soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) required for late endosome-lysosome and homotypic lysosome fusion in vitro. A bacterially expressed human Syntaxin 7 lacking the transmembrane domain inhibited homotypic late endosome and lysosome fusion as well as heterotypic late endosome-lysosome fusion. Affinity-purified antibodies directed against Syntaxin 7 also inhibited lysosome fusion in vitro but had no affect on homotypic early endosome fusion. Previous work suggested that human VAMP-7 (vesicle-associated membrane protein-7) was a SNARE required for late endosome-lysosome fusion. A bacterially expressed human VAMP-7 lacking the transmembrane domain inhibited both late endosome-lysosome fusion and homotypic lysosome fusion in vitro. These studies indicate that: 1) fusion along the endocytic pathway is a highly regulated process, and 2) two SNARE molecules, Syntaxin 7 and human VAMP-7, are involved in fusion of vesicles in the late endocytic pathway in alveolar macrophages.     

Acidification of endosome subpopulations in wild-type Chinese hamster ovary cells and temperature-sensitive acidification-defective mutants

During endocytosis in Chinese hamster ovary (CHO) cells, Semliki Forest virus (SFV) passes through two distinct subpopulations of endosomes before reaching lysosomes. One subpopulation, defined by cell fractionation using free flow electrophoresis as "early endosomes," constitutes the major site of membrane and receptor recycling; while "late endosomes," an electrophoretically distinct endosome subpopulation, are involved in the delivery of endosomal content to lysosomes. In this paper, the pH-sensitive conformational changes of the SFV E1 spike glycoprotein were used to study the acidification of these defined endosome subpopulations in intact wild-type and acidification-defective CHO cells. Different virus strains were used to measure the kinetics at which internalized SFV was delivered to endosomes of pH less than or equal to 6.2 (the pH at which wild-type E1 becomes resistant to trypsin digestion) vs. endosomes of pH less than or equal to 5.3 (the threshold pH for E1 of the SFV mutant fus-1). By correlating the kinetics of acquisition of E1 trypsin resistance with the transfer of SFV among distinct endosome subpopulations defined by cell fractionation, we found that after a brief residence in vesicles of relatively neutral pH, internalized virus encountered pH less than or equal to 6.2 in early endosomes with a t1/2 of 5 min. Although a fraction of the virus reached a pH of less than or equal to 5.3 in early endosomes, most fus-1 SFV did not exhibit the acid-induced conformational change until arrival in late endosomes (t1/2 = 8-10 min). Thus, acidification of both endosome subpopulations was heterogeneous. However, passage of SFV through a less acidic early endosome subpopulation always preceded arrival in the more acidic late endosome subpopulation. In mutant CHO cells with temperature-sensitive defects in endosome acidification in vitro, acidification of both early and late endosomes was found to be impaired at the restrictive temperature (41 degrees C). The acidification defect was also found to be partially penetrant at the permissive temperature, resulting in the inability of any early endosomes in these cells to attain pH less than or equal to 5.3. In vitro studies of endosomes isolated from mutant cells suggested that the acidification defect is most likely in the proton pump itself. In one mutant, this defect resulted in increased sensitivity of the electrogenic H+ pump to fluctuations in the endosomal membrane potential.     

大鼠肾近球小管细胞胞饮体膜氢泵活性和水的渗透性转运的特征

本实验采用异硫氰酸-葡聚糖荧光素(fluorescein isothiocyanate-dextran,FITC-dextran)体内标记法,研究大鼠肾近球小管细胞胞饮体(endosome)膜上 H~+-ATP 酶的活性及水的渗透性转运。通过观察在胞饮体外加入一定量 ATP 后,胞饮体内 pH 值的时间反应曲线,从而测定 ATP-依赖的 H~+在胞饮体膜上的转运情况。胞饮体内的酸化速度及 pH 的最低值与加入的 ATP 浓度有关。在加入 ATP 前,胞饮体内的 pH 值为7.4,加入不同浓度的 ATP 后,即[ATP]为0.005,0.05,0.5,5和10mmol/L,胞饮体内 pH 最低值分别为7.30,6.99,6.68,6.38和6.39。此种由 ATP 引起的酸化反应,被0.5mmol/L N-ethylmaleimide(NEM)抑制97%,但不被钒酸盐和 oligomycin 所抑制。实验还同时观察了此种胞饮体水的渗透性转运机制。通过在胞饮体膜内外建立一个蔗糖浓度梯度。观察 FITC-dextran 荧光信号的快速动力学变化过程,从而测定由于渗透压梯度引起的水在胞饮体膜上转运的特征。在230℃时,水的渗透性通透系数(osmotic water permeability coefficient,P_f)为0.03cm/s;加入0.5mmol/L HgCl_2后,水的转运被抑制70%。此抑制反应可被5mmol/L 巯基乙醇(β-Mcrcaptoethanol)完全逆转。上述结果提示:大鼠肾近球小管胞饮体膜含有H~+-ATP 酶和水的转运通道。胞饮     

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.     

Subpopulations of endosomes generated at sequential stages in the endocytic pathway of asialoganglioside-containing ferrite ligands in rat liver

Subpopulations of endosomes generated at different stages of the endocytic pathway were isolated by a high-gradient magnetic separation followed by a Percoll density gradient centrifugation. Rat livers were perfused for 5 min with asialoganglioside (ASG)-containing ferrite particles and chased at 37 degrees C. At various times after the internalization, the endocytic vesicles containing ferrite particles were isolated by the magnetic separation. Isolated fractions contained endosomes until 15-min perfusion, after which most of the particles were transported to lysosomes. The endosomal fractions isolated after the 5- or 15-min perfusions were further analyzed by 30% Percoll density gradient centrifugation. The endosomes after 5-min perfusion showed peaks around the density of 1.05 g/ml (peak I) and 1.07 g/ml (peak Is), both of which contained asialoglycoprotein receptors. In the 15-min perfusion, another peak of endosomes (peak II) was observed at the higher density of 1.09 g/ml without the receptors, in addition to peak I. These endosomes had their own characteristic proteins. Some proteins were common in the subgroups of endosomes. These results suggest that the endosome I containing the ligands and the receptors was first produced after endocytosis and, through the endosome is, was scissioned into the endosome II containing the ligands. The endosome II was then fused with primary lysosomes for proteolytic cleavage of ligands.     

Azithromycin, a lysosomotropic antibiotic, impairs fluid-phase pinocytosis in cultured fibroblasts

The dicationic macrolide antibiotic azithromycin inhibits the uptake of horseradish peroxidase (HRP) by fluid-phase pinocytosis in fibroblasts in a time- and concentration-dependent fashion without affecting its decay (regurgitation and/or degradation). The azithromycin effect is additive to that of nocodazole, known to impair endocytic uptake and transport of solutes along the endocytic pathway. Cytochemistry (light and electron microscopy) shows a major reduction by azithromycin in the number of HRP-labeled endocytic vesicles at 5 min (endosomes) and 2 h (lysosomes). Within 3 h of exposure, azithromycin also causes the appearance of large and light-lucentlelectron-lucent vacuoles, most of which can be labeled by lucifer yellow when this tracer is added to culture prior to azithromycin exposure. Three days of treatment with azithromycin result in the accumulation of very large vesicles filled with pleiomorphic content, consistent with phospholipidosis. These vesicles are accessible to fluorescein-labeled bovine serum albumin (FITC-BSA) and intensively stained with filipin, indicating a mixed storage with cholesterol. The impairment of HRP pinocytosis directly correlates with the amount of azithromycin accumulated by the cells, but not with the phospholipidosis induced by the drug. The proton ionophore monensin, which completely suppresses azithromycin accumulation, also prevents inhibition of HRP uptake. Erythromycylamine, another dicationic macrolide, also inhibits HRP pinocytosis in direct correlation with its cellular accumulation and is as potent as azithromycin at equimolar cellular concentrations. We suggest that dicationic macrolides inhibit fluid-phase pinocytosis by impairing the formation of pinocytic vacuoles and endosomes.     

Internalization and delivery to lysosomes of hydrazide horseradish peroxidase, a covalent membrane probe

Hydrazide horseradish peroxidase, (hydHRP), a hydrazide derivative of the common cytochemical tracer HRP, was covalently coupled to the surface of periodate-treated Chinese hamster ovary (CHO) cells and used to study the distribution and internalization of plasma membrane glycoconjugates. The Schiff-base coupling of hydHRP to the cell surface at 4 degrees C had little effect on cell viability. After coupling, cells were washed at 4 degrees C and the subcellular distribution of hydHRP was determined immediately or after incubation at 37 degrees C. Within 1 hr, hydHRP was observed to cap over pseudopodal-like extensions and then accumulate over a 2.5 h period in a punctate to perinuclear staining pattern over the cell body. By electron microscopy, the pseudopodal-like regions were found to be areas of extensive cell surface invaginations, rich in microfilaments. HydHRP internalized over a 2.5 to 18 hr period was observed in smooth vesicles resembling pinosomes/endosomes, multivesicular bodies (lysosomes), and small perinuclear vesicles. Little, if any, hydHRP activity was detected in association with elements of Golgi apparatus. By cell fractionation in 10% Percoll gradients, hydHRP was found to have accumulated in prelysosomal endocytic vesicles and lysosomes. For cells that were first surface labeled with 125I at 4 degrees C and then conjugated with hydHRP, little, if any, cotransport of the 125I label with hydHRP was observed. Over the entire capping and internalization period, most hydHRP activity remained membrane associated. Overall, these results indicate that the dominant intracellular transport route for a covalent membrane probe, hydHRP glycoconjugate, is similar if not identical to that previously reported for the solute probe native HRP (16) in CHO cells. HydHRP internalization provides further evidence for the independent sorting of proteins in endocytic transport.     

Kinetics of endosome acidification detected by mutant and wild-type Semliki Forest virus.

The fusogenic properties of Semliki Forest virus (SFV) and its mutants were used to follow the kinetics of acidification during the endocytic uptake of virus by BHK-21 cells. It has previously been shown that the low pH of endocytic vacuoles triggers a conformational change in the SFV spike glycoprotein, activating membrane fusion and initiating virus infection. This conformational alteration was here shown to occur in endosomes and to follow the same time course as the intracellular fusion reaction, demonstrating that fusion occurs rapidly after virus exposure to endosome acidity. The kinetics of endosome acidification were monitored using wild type (wt) SFV and fus-1, an SFV mutant with a lower fusion pH threshold. The results presented here demonstrated that wt and mutant virus were internalized with a t1/2 of 10 min, and that endosomes were acidified to the wt threshold of pH 6.2 with a t1/2 of 15 min. In contrast, endosome pH reached the fus-1 threshold of 5.3 with a much longer t1/2 of 45 min. The subsequent degradation of SFV in lysosomes had a t1/2 of 90 min. It was found that after the initial uptake of virus from the plasma membrane, its transit through the endocytic pathway, exposure to endosome acidity and eventual delivery to lysosomes were markedly asynchronous.     

Cell-free systems to study vesicular transport along the secretory and endocytic pathways

Proteins bound for the cell surface, lysosomes, and secretory storage granules share a common pathway of intracellular transport. After their synthesis and translocation into the endoplasmic reticulum, these proteins traverse the secretory pathway by a series of vesicular transfers. Similarly, nutrient and signaling molecules enter cells by endocytosis, and move through the endocytic pathway by passage from one membrane-bound compartment to another. Little is known about the mechanisms by which proteins are collected into transport vesicles, or how these vesicles form, identify their targets, and subsequently fuse with their target membranes. An important advance toward our understanding these processes has come from the establishment of cell-free systems that reconstitute vesicular transfers in vitro. It is now possible to measure, in vitro, the transport of proteins from the endoplasmic reticulum to the Golgi, between Golgi cisternae, and the formation of transport vesicles en route from the trans Golgi network to the cell surface. Along the endocytic pathway, cell-free systems are available to study clathrin-coated vesicle formation, early endosome fusion, and the fusion of late endosomes with lysosomes. Moreover, the selective movement of receptors between late endosomes and the trans Golgi network has also been reconstituted. The molecular mechanisms of vesicular transport are now amenable to elucidation.     

Endocytosis, intracellular transport, and turnover of anionic and cationic proteins in cultured mouse peritoneal macrophages

It was previously shown that cultured mouse peritoneal macrophages ingest anionic derivatives of horseradish peroxidase (HRP) and ferritin by fluid-phase endocytosis and accumulate them in lysosomes. Cationic derivatives were taken up by adsorptive endocytosis and transported to lysosomes but subsequently appeared also in stacked cisternae, tubules, and vesicles of the Golgi complex. In the present investigation, the effect of molecular net charge on the rate of cellular inactivation of a protein was studied. The results demonstrate that anionized HRP was inactivated at a higher initial rate than cationized HRP. This is in agreement with the finding that the cationic protein partly escaped from the digestive compartment of the cells, that means the lysosomes. The effects of phorbol myristate acetate (PMA)--a diterpene ester and a tumor promoter--and monensin--a carboxylic ionophore and a perturbant of the Golgi complex--on fluid-phase endocytosis of HRP and intracellular transport of cationized ferritin (CF) were also studied. PMA stimulated fluid-phase endocytosis of HRP but did not interfere with transport of CF to the Golgi complex. Contrarily, monensin inhibited uptake of HRP and almost totally blocked transport of CF to the Golgi complex. The findings support the idea that membrane and content of endocytic vesicles are treated separately. The content is emptied into lysosomes where macromolecular material normally is degraded. The membrane becomes part of the lysosomal envelope in connection with endocytic vesicle-lysosome fusion. Subsequently, membrane patches are detached from the lysosomes and reutilized. This is at least partly mediated via the Golgi complex and particularly its tubular and vesicular parts. Since the cationic tracers do not bind to the membrane in a stable way, it is not possible to extend the conclusions to individual membrane constituents.     

Characterization of the early endosome and putative endocytic carrier vesicles in vivo and with an assay of vesicle fusion in vitro

We have investigated two aspects of membrane traffic at early stages of endocytosis: membrane fusion and microtubule-dependent transport. As a marker, we have used the trans-membrane glycoprotein G of vesicular stomatitis virus implanted into the plasma membrane and then internalized for different times at 37 degrees C. The corresponding endosomal fractions were immunoisolated using the cytoplasmic domain of the G protein as antigen. These fractions were then used in an in vitro assay to quantify the efficiency of fusion between endosomal vesicles. To identify the vesicular partners of the fusion, these in vitro studies were combined with in vivo biochemical and morphological experiments. Internalized molecules were delivered to early endosomal elements, which corresponded to a network of tubular and tubulovesicular structures. Rapid recycling back to the plasma membrane and routing to late stages of the pathway occurred from these early endosomal elements. These elements exhibited a high and specific fusion activity with each other in vitro, suggesting that individual elements of the early endosomal compartment interact with each other in vivo. After their appearance in the early endosome, the molecules destined to be degraded were observed at the next stage of the pathway in distinct spherical vesicles (0.5 micron diam) and then in late endosomes and lysosomes. When the microtubules were depolymerized with nocodazole, endocytosis proceeded as in control cells. However, internalized molecules remained in the spherical vesicles and did not appear in late endosomes or lysosomes. These spherical vesicles had relatively little fusion activity with each other or with early endosomal elements in vitro. Our observations suggest that the spherical vesicles mediate transport between the early endosome and late endosomes and that this process requires intact microtubules.     

Selective membrane recruitment of EEA1 suggests a role in directional transport of clathrin-coated vesicles to early endosomes

The molecular mechanisms ensuring directionality of endocytic membrane trafficking between transport vesicles and target organelles still remain poorly characterized. We have been investigating the function of the small GTPase Rab5 in early endocytic transport. In vitro studies have demonstrated a role of Rab5 in two membrane fusion events: the heterotypic fusion between plasma membrane-derived clathrin-coated vesicles (CCVs) and early endosomes and in the homotypic fusion between early endosomes. Several Rab5 effectors are required in homotypic endosome fusion, including EEA1, which mediates endosome membrane docking, as well as Rabaptin-5 x Rabex-5 complex and phosphatidylinositol 3-kinase hVPS34. In this study we have examined the localization and function of Rab5 and its effectors in heterotypic fusion in vitro. We report that the presence of active Rab5 is necessary on both CCVs and early endosomes for a heterotypic fusion event to occur. This process requires EEA1 in addition to the Rabaptin-5 complex. However, whereas Rab5 and Rabaptin-5 are symmetrically distributed between CCVs and early endosomes, EEA1 is recruited selectively onto the membrane of early endosomes. Our results suggest that EEA1 is a tethering molecule that provides directionality to vesicular transport from the plasma membrane to the early endosomes.     

The mannose 6-phosphate receptor and the biogenesis of lysosomes

Localization of the 215 kd mannose 6-phosphate receptor (MPR) was studied in normal rat kidney cells. Low levels of receptor were detected in the trans Golgi network, Golgi stack, plasma membrane, and peripheral endosomes. The bulk of the receptor was localized to an acidic, reticular-vesicular structure adjacent to the Golgi complex. The structure also labeled with antibodies to lysosomal enzymes and a lysosomal membrane glycoprotein (lgp120). While lysosome-like, this structure is not a typical lysosome that is devoid of MPRs. The endocytic marker alpha 2 macroglobulin-gold entered the structure at 37 degrees C, but not at 20 degrees C. With prolonged chase, most of the marker was transported from the structure into lysosomes. We propose that the MPR/lgp-enriched structure is a specialized endosome (prelysosome) that serves as an intermediate compartment into which endocytic vesicles discharge their contents, and where lysosomal enzymes are released from the MPR and packaged along with newly synthesized lysosomal glycoproteins into lysosomes.     

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 role for Rab5 activity in the biogenesis of endosomal and lysosomal compartments

Rab5 is a small GTPase that plays roles in the homotypic fusion of early endosomes and regulation of intracellular vesicle transport. We show here that expression of GFP-tagged GTPase-deficient form of Rab5b (Rab5bQ79L) in NRK cells results in the sequential formation of three morphologically and functionally distinct types of endosomes. Expression of GFP-Rab5bQ79L initially caused a homotypic fusion of early endosomes accompanying a redistribution of the TGN-resident cargo molecules, and subsequent fusion with late endosomes/lysosomes, leading to the formation of giant hybrid organelles with features of early endosomes and late endosomes/lysosomes. Surprisingly, the giant endosomes gradually fragmented and shrunk, leading to the accumulation of early endosome clusters and concurrent reformation of late endosomes/lysosomes, a process accelerated by treatment with a phosphatidylinositol-3-kinase (PI(3)K) inhibitor, wortmannin. We postulate that such sequential processes reflect the biogenesis and maintenance of late endosomes/lysosomes, presumably via direct fusion with early endosomes and subsequent fission from hybrid organelles. Thus, our findings suggest a regulatory role for Rab5 in not only the early endocytic pathway, but also the late endocytic pathway, of membrane trafficking in coordination with PI(3)K activity.     

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.     

Disruption of the actin filament network affects delivery of endocytic contents marker to phagosomes with early endosome characteristics: the case of phagosomes with pathogenic mycobacteria

Phagosomes containing live virulent mycobacteria undergo fusion with early endosomes, but they are unable to mature normally. Accordingly, they do not fuse with lysosomes. Although M. avium-containing phagosomes retain fusion and intermingling characteristics of early endosomes indefinitely, fusions with early endosomes are increasingly restricted as bacteria multiply. In addition, when endocytic tracers, such as horseradish peroxidase (HRP), are added to M. avium-infected macrophages at 1 or up to 15 days after infection, an atypical time course of acquisition of the tracer by the phagosomes is observed, i.e., a 10 to 20 min lag, instead of immediate acquisition as is typical for early endosomes (and phagosomes with early endosome characteristics). These events coincide with a marked disorganization of the actin filament network in M. avium-infected macrophages. In the present study, we have therefore addressed the following question: Do actin filaments play a role in fusion and intermingling of contents between early endosomes and immature phagosomes that undergo homotypic fusion with early endosomes? We examined the time course of acquisition of subsequently internalized endocytic marker (HRP) by early endosome-like preexisting phagosomes, i.e. 2 hour-old phagosomes with either hydrophobic latex particles, virulent or avirulent M. avium, after depolymerization of the actin filament network with cytochalasin D or after repolymerization of the actin filament network with jasplakinolide, in cases where the network had been depolymerized (macrophages infected with M. avium, at 1 or up to 7 days after infection). By direct morphological observation at the electron microscope level and by a kinetic approach, we show here that depolymerization of the actin filament network with cytochalasin D delays acquisition of HRP whereas repolymerization restores immediate acquisition of the marker. We conclude that the actin filament network is involved in fusion and intermingling of endocytic contents between early endosomes and early endosome-like phagosomes, and that disruption of this network by M. avium is the cause for the atypical acquisition of content marker by phagosomes containing these pathogenic mycobacteria.