New liver cell mutants defective in the endocytic pathway

To isolate mutant liver cells defective in the endocytic pathway, a selection strategy using toxic ligands for two distinct membrane receptors was utilized. Rare survivors termed trafficking mutants (Trf2-Trf7) were stable and more resistant than the parental HuH-7 cells to both toxin conjugates. They differed from the previously isolated Trf1 HuH-7 mutant as they expressed casein kinase 2 alpha' (CK2alpha') which is missing from Trf1 cells and which corrects the Trf1 trafficking phenotype. Binding of (125)I-asialoorosomucoid (ASOR) and cell surface expression of asialoglycoprotein receptor (ASGPR) were reduced approximately 20%-60% in Trf2-Trf7 cells compared to parental HuH-7, without a reduction in total cellular ASGPR. Based on (125)I-transferrin binding, cell surface transferrin receptor activity was reduced between 13% and 88% in the various mutant cell lines. Distinctive phenotypic traits were identified in the differential resistance of Trf2-Trf7 to a panel of lectins and toxins and to UV light-induced cell death. By following the endocytic uptake and trafficking of Alexa(488)-ASOR, significant differences in endosomal fusion between parental HuH-7 and the Trf mutants became apparent. Unlike parental HuH-7 cells in which the fusion of endosomes into larger vesicles was evident as early as 20 min, ASOR endocytosed into the Trf mutants remained within small vesicles for up to 60 min. Identifying the biochemical and genetic mechanisms underlying these phenotypes should uncover novel and unpredicted protein-protein or protein-lipid interactions that orchestrate specific steps in membrane protein trafficking.     

New liver cell mutants defective in the endocytic pathway

To isolate mutant liver cells defective in the endocytic pathway, a selection strategy using toxic ligands for two distinct membrane receptors was utilized. Rare survivors termed trafficking mutants (Trf2-Trf7) were stable and more resistant than the parental HuH-7 cells to both toxin conjugates. They differed from the previously isolated Trf1 HuH-7 mutant as they expressed casein kinase 2 α″ (CK2α″) which is missing from Trf1 cells and which corrects the Trf1 trafficking phenotype. Binding of ¹²⁵I-asialoorosomucoid (ASOR) and cell surface expression of asialoglycoprotein receptor (ASGPR) were reduced approximately 20%-60% in Trf2-Trf7 cells compared to parental HuH-7, without a reduction in total cellular ASGPR. Based on ¹²⁵I-transferrin binding, cell surface transferrin receptor activity was reduced between 13% and 88% in the various mutant cell lines. Distinctive phenotypic traits were identified in the differential resistance of Trf2-Trf7 to a panel of lectins and toxins and to UV light-induced cell death. By following the endocytic uptake and trafficking of Alexa₄₈₈-ASOR, significant differences in endosomal fusion between parental HuH-7 and the Trf mutants became apparent. Unlike parental HuH-7 cells in which the fusion of endosomes into larger vesicles was evident as early as 20 min, ASOR endocytosed into the Trf mutants remained within small vesicles for up to 60 min. Identifying the biochemical and genetic mechanisms underlying these phenotypes should uncover novel and unpredicted protein-protein or protein-lipid interactions that orchestrate specific steps in membrane protein trafficking.     

Cohort movement of different ligands and receptors in the intracellular endocytic pathway of alveolar macrophages

The rate of movement of different receptors and ligands through the intracellular endocytic apparatus was studied in alveolar macrophages. Cells were exposed to iodinated alpha-macroglobulin-protease complexes, mannose terminal glycoproteins, diferric transferrin, and maleylated proteins. By use of the diaminobenzidine density shift procedure, we demonstrated that these ligands were internalized into the same endocytic vesicle. We then compared the rates of transfer to the lysosome or recycling to the cell surface of different ligands/receptors contained in the same endosome. We found that although the rate constant for degradation was ligand specific, the lag time prior to the initiation of degradation was the same for all three ligands. We also found that molecules taken up nonspecifically by fluid-phase pinocytosis had the same lag time prior to degradation as ligands internalized via receptor-mediated endocytosis. These data suggest that different molecules within the same endocytic compartment are transferred to the lysosome (or degradative compartment) at the same rate. We measured the rate of return of receptors to the cell surface by either inactivating surface receptors by protease treatment at 0 degrees C, or by incubating cells with saturating amounts of nonradioactive ligand at 37 degrees C. We then measured the rate of appearance of "new" receptors on the cell surface. Using these approaches, we found that three different receptors were transferred from internal pools to the cell surface at the same rate. The rate of transfer was independent of whether receptors were initially occupied or unoccupied. Our observations indicate that receptor/ligands, once inside alveolar macrophages, are transported by vesicles which transfer their contents as a cohort from one compartment to another. The rate of movement of these receptors is determined by the movement of vesicles and is independent of their content.     

Selective degradation of insulin within rat liver endosomes

To characterize the role of the endosome in the degradation of insulin in liver, we employed a cell-free system in which the degradation of internalized 125I-insulin within isolated intact endosomes was evaluated. Incubation of endosomes containing internalized 125I-insulin in the cell-free system resulted in a rapid generation of TCA soluble radiolabeled products (t1/2, 6 min). Sephadex G-50 chromatography of radioactivity extracted from endosomes during the incubation showed a time dependent increase in material eluting as radioiodotyrosine. The apparent Vmax of the insulin degrading activity was 4 ng insulin degraded.min-1.mg cell fraction protein-1 and the apparent Km was 60 ng insulin.mg cell fraction protein-1. The endosomal protease(s) was insulin-specific since neither internalized 125I-epidermal growth factor (EGF) nor 125I-prolactin was degraded within isolated endosomes as assessed by TCA precipitation and Sephadex G-50 chromatography. Significant inhibition of degradation was observed after inclusion of p-chloromercuribenzoic acid (PCMB), 1,10-phenanthroline, bacitracin, or 0.1% Triton X-100 into the system. Maximal insulin degradation required the addition of ATP to the cell-free system that resulted in acidification as measured by acridine orange accumulation. Endosomal insulin degradation was inhibited markedly in the presence of pH dissipating agents such as nigericin, monensin, and chloroquine or the proton translocase inhibitors N-ethylmaleimide (NEM) and dicyclohexylcarbodiimide (DCCD). Polyethylene glycol (PEG) precipitation of insulin-receptor complexes revealed that endosomal degradation augmented the dissociation of insulin from its receptor and that dissociated insulin was serving as substrate to the endosomal protease(s). The results suggest that as insulin is internalized it rapidly but incompletely dissociates from its receptor. Dissociated insulin is then degraded by an insulin specific protease(s) leading to further dissociation and degradation.     

Membrane insertion of anthrax protective antigen and cytoplasmic delivery of lethal factor occur at different stages of the endocytic pathway

The protective antigen (PA) of anthrax toxin binds to a cell surface receptor, undergoes heptamerization, and binds the enzymatic subunits, the lethal factor (LF) and the edema factor (EF). The resulting complex is then endocytosed. Via mechanisms that depend on the vacuolar ATPase and require membrane insertion of PA, LF and EF are ultimately delivered to the cytoplasm where their targets reside. Here, we show that membrane insertion of PA already occurs in early endosomes, possibly only in the multivesicular regions, but that subsequent delivery of LF to the cytoplasm occurs preferentially later in the endocytic pathway and relies on the dynamics of internal vesicles of multivesicular late endosomes.     

A novel assay to demonstrate an intersection of the exocytic and endocytic pathways at early endosomes

The mechanism of transport of membrane proteins from the trans-Golgi to the cell surface is still poorly understood. Previous studies suggested that basolateral membrane proteins, such as the transferrin receptor and the asialoglycoprotein receptor H1, take an indirect route to the plasma membrane via an intracellular, most likely endosomal intermediate. To define this compartment we developed a biochemical assay based on the very definition of endosomes. The assay is based on internalizing anti-H1 antibodies via the endocytic cycle of the receptor itself. Internalized antibody formed immune complexes with newly synthesized H1, which had been pulse-labeled with [(35)S]sulfate and chased out of the trans-Golgi for a period of time that was insufficient for H1 to reach the surface. Hence, antibody capture occurred intracellularly. Double-immunofluorescence labeling demonstrated that antibody-containing compartments also contained transferrin and thus corresponded to early and recycling endosomes. The results therefore demonstrate an intracellular intersection of the exocytic and endocytic pathways with implications for basolateral sorting.     

ESCRTing proteins in the endocytic pathway

The endosomal sorting complex required for transport (ESCRT) machinery is highly conserved and its components have been found in all five major supergroups of eukaryotes. The three ESCRT complexes and associated proteins play critical roles in receptor downregulation, retroviral budding, and other normal and pathological cellular processes. Besides monoubiquitin-dependent protein cargo recognition and sorting, the ESCRT machinery also appears to drive the formation of multivesicular bodies (MVBs). Recent advances in the determination of the function and structure of the ESCRT complexes have improved our understanding of the molecular details underlying the assembly and regulation of the ESCRT machinery.     

Lipid domains in the endocytic pathway

Whereas endosomes connect with both exocytic and endocytic organelle via extensive lipid and protein traffic, each endosome has a distinct lipid and protein composition. Recent observations suggest that different lipid membrane domains exist even in the same endosome. These lipid domains, together with low pH milieu, may present a variety of micro-environments to cargo molecules. Evidence is accumulating which suggests that the alteration of these lipid microdomains may be involved in a number of pathological conditions.     

Purification and subunit characterization of the rat liver endocytic hyaluronan receptor

The endocytic hyaluronan (HA) receptor of liver sinusoidal endothelial cells (LECs) is responsible for the clearance of HA and other glycosaminoglycans from the circulation in mammals. We report here for the first time the purification of this liver HA receptor. Using lectin and immuno-affinity chromatography, two HA receptor species were purified from detergent-solubilized membranes prepared from purified rat LECs. In nonreducing SDS-polyacrylamide gel electrophoresis (PAGE), these two proteins migrated at 175- and approximately 300 kDa corresponding to the two species previously identified by photoaffinity labeling of live cells as the HA receptor (Yannariello-Brown, J., Frost, S. J., and Weigel, P. H. (1992) J. Biol. Chem. 267, 20451-20456). These two proteins co-purify in a molar ratio of 2:1 (175:300), and both proteins are active, able to bind HA after SDS-PAGE, electrotransfer, and renaturation. After reduction, the 175-kDa protein migrates as a approximately 185-kDa protein and is not able to bind HA. The 300-kDa HA receptor is a complex of three disulfide-bonded subunits that migrate in reducing SDS-PAGE at approximately 260, 230, and 97 kDa. These proteins designated, respectively, the alpha, beta, and gamma subunits are present in a molar ratio of 1:1:1 and are also unable to bind HA when reduced. The 175-kDa protein and all three subunits of the 300-kDa species contain N-linked oligosaccharides, as indicated by increased migration in SDS-PAGE after treatment with N-glycosidase F. Both of the deglycosylated, nonreduced HA receptor proteins still bind HA.     

Acidification and ion permeabilities of highly purified rat liver endosomes

While it is well established that acidic pH in endosomes plays a critical role in mediating the orderly traffic of receptors and ligands during endocytosis, little is known about the bioenergetics or regulation of endosome acidification. Using highly enriched fractions of rat liver endosomes prepared by free flow electrophoresis and sucrose density gradient centrifugation, we have analyzed the mechanism of ATP-dependent acidification and ion permeability properties of the endosomal membrane. This procedure permitted the isolation of endosome fractions which were up to 200-fold enriched as indicated by the increased specific activity of ATP-dependent proton transport. Acidification was monitored using hepatocyte and total liver endosomes selectively labeled with pH-sensitive markers of receptor-mediated endocytosis (fluorescein isothiocyanate asialoorosomucoid) or fluid-phase endocytosis (fluorescein isothiocyanate-dextran). In addition, changes in membrane potential accompanying ATP-dependent acidification were directly measured using the voltage-sensitive fluorescent dye Di-S-C3(5). Our results indicate that ATP-dependent acidification of liver endosomes is electrogenic, with proton transport being accompanied by the generation of an interior-positive membrane potential opposing further acidification. The membrane potential can be dissipated by the influx of permeant external anions or efflux of internal alkali cations. Replacement externally of permeable anions with less permeable anions (e.g. replacing Cl- with gluconate) diminished acidification, as did replacement internally of a more permeant cation K+ with less permeant species (such as Na+ or tetramethylammonium). ATP-dependent H+ transport was not coupled to any specific anion or cation, however. The endosomal membrane was found to be extremely permeable to protons, with protons able to leak out almost as fast as they are pumped in. Thus, the internal pH of endosomes is likely to reflect a dynamic equilibrium of protons regulated by the intrinsic ion permeabilities of the endosomal membrane, in addition to the activity of an ATP-driven proton pump.     

Oxidative activity in mitochondria isolated from rat liver at different stages of development

The purpose of this study was to evaluate the oxidative capacities in hepatic mitochondria isolated from prepubertal, young adult and adult rats (40, 90 and 180 days of age, respectively). In these rats, mitochondrial respiratory rates using FAD- and NAD-linked substrates as well as mitochondrial protein mass were measured. The results show that only the oxidative capacity of FAD-linked pathways significantly declined in mitochondria from 180-day-old rats compared with those from younger animals. When we consider FAD-linked respiration expressed per g liver, no significant difference was found among rats of different ages because of an increased mitochondrial protein mass found in 180-day-old rats. However, when FAD-linked and lipid-dependent respiratory rates were expressed per 100 g body weight, significant decreases occurred in 180-day-old rats. Therefore, the decrease in liver weight expressed per 100 g body weight rather than an impaired hepatic cellular activity may be the cause of body energy deficit in 180-day-old rats. Copyright © 1998 John Wiley & Sons, Ltd.     

Oiling the wheels of the endocytic pathway

An ever more complete picture of the organization and function of the endocytic pathway is emerging. New mechanisms, and in particular lipid-based mechanisms that couple membrane dynamics and sorting, are being unraveled. But the final picture is still coming into focus as new membrane domains, cell entry pathways and compartments come into view. Of special interest are the recent findings that pathogenic agents, in contrast to scientists, seem to have long discovered how to subvert membrane specialization to their own advantage.     

Ordering of compartments in the yeast endocytic pathway

We have characterized the morphology of the yeast endocytic pathway leading from the plasma membrane to the vacuole by following the trafficking of positively charged nanogold in combination with compartment identification using immunolocalization of t-SNARE proteins. The first endocytic compartment, termed the early/recycling endosome, contains the t-SNARE, Tlg1p. The next compartment, the prevacuolar compartment, contains Pep12p. After transport to the prevacuolar compartment, where vacuolar enzymes are seen on their way to the vacuole, endocytic content is delivered to the late endosome and on to the vacuole, both of which are devoid of Pep12p immunolabel. Traffic to the prevacuolar compartment is reduced in strains mutant for the Rab5 homologs, Vps21p, Ypt52p, and Ypt53p and in vps27 mutant cells. On the other hand, traffic to the early recycling endosome is less dependent on Rab5 homologs and does not require Vps27p.     

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

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

Distribution of G-proteins in rat liver plasma-membrane domains and endocytic pathways.

Cryoenzymology techniques were used to facilitate trapping an acyl-enzyme intermediate in beta-lactamase I catalysis. The enzyme (from Bacillus cereus) was investigated in aqueous methanol cryosolvents over the 25 to -75 degrees C range, and was stable and functional in 70% (v/v) methanol at and below 0 degree C. The value of kcat. decreased linearly with increasing methanol concentration, suggesting that water is a reactant in the rate-determining step. In view of this, the lack of incorporation of methanol into the product means that the water molecule involved in the deacylation is shielded from bulk solvent in the enzyme-substrate complex. From the lack of adverse effects of methanol on the catalytic and structural properties of the enzyme we conclude that 70% methanol is a satisfactory cryosolvent system for beta-lactamase I. The acyl-enzyme intermediate from the reaction with 6-beta-(furylacryloyl)amidopenicillanic acid was accumulated in steady-state experiments at -40 degrees C and the reaction was quenched by lowering the pH to 2. H.p.l.c. experiments showed covalent attachment of the penicillin to the enzyme. Digestion by pepsin and trypsin yielded a single labelled peptide fragment; analysis of this peptide was consistent with Ser-70 as the site of attachment.     

A cell-free analysis of the endocytic pathway

The molecular control of the endocytic pathway is poorly understood. To obtain this information requires the use of cell-free systems which faithfully recreate the various endocytic events as they occur in the intact cell. Here I describe our approach to elucidating the mechanism which controls the fusion between different vesicles on the pathway.