Pathways followed by membrane recovered from the surface of plasma cells and myeloma cells

Membrane recycling in secretory cells: pathway to the Golgi complex

The pathway taken by membrane that is recovered by endocytosis from the surface of secretory cells was investigated with electron-dense tracers 9dextrans and cationized ferritin). The cell types examined included exocrine cells of the parotid and lacrimal glands, endocrine cells of the anterior pituitary gland, and immunoglobulin-secreting cells from lymph nodes or myeloma cell lines. In all cases, when the cells were incubated at 37 degrees C the tracers were initially taken up by endocytosis and they later appeared in the stacked Golgi cisternae, in immature secretion granules or vacuoles and in lysosomes. Similar results were obtained after covalent labelling of surface membrane constituents when myeloma cells were radioiodinated and the fate of the labelled components was followed by autoradiography. Initially only the cell surface was labelled, and the autoradiographic grains were concentrated over the plasmalemma. After incubation at 37 degrees C some of the labelled components were internalized (by endocytosis), and the majority of the internal autoradiographic grains were found over Golgi cisternae and over associated secretory vacuoles, which were the only organelles significantly labelled. The findings indicate the existence of considerable membrane traffic from the plasmalemma to the stacked Golgi cisternae and forming secretion granules or vacuoles in all these cell types. Membrane is thus continually recovered from the cell surface of secretory cells and funnelled through the Golgi complex; moreover, the plasmalemma-to-Golgi traffic appears to represent a major route of membrane traffic in secretory cells. A large portion of this traffic appears to be associated with the recycling of the membrane containers used in the packaging of secretory products.

Receptor-mediated transport of IgG across the intestinal epithelium of the neonatal rat

The absorptive epithelium of the neonatal rat is developmentally specialized to transfer maternal immunoglobulin G (IgG) intact to the circulation while other milk protein are digested. The epithelial cells of the duodenum and proximal jejunum which are responsible for IgG transfer represent a particular striking experimental model for study of receptor-mediated intracellular transport. Receptors located on the luminal plasma membrane selectively bind the Fc region of IgG. The IgG enters the cell by constitutive endocytosis within coated vesicles and is then released at the basolateral plasma membrane. Morphological evidence supports a model in which IgG crosses the cell as a ligand-receptor complex that dissociates only on exposure to a pH 7.4 environment found at the basolateral cell surface. Although uptake of IgG at the luminal plasma membrane is highly selective, small but significant amounts of other proteins enter the cell apparently non-selectively. Nevertheless, these latter proteins are not transferred across the cell. Double-tracer experiments indicate that IgG and these other proteins enter the cell simultaneously within the same endocytic vesicles, but that non-membrane-bound proteins are removed from the IgG transport pathway by an as yet poorly defined mechanism and sequestered within small apical vacuoles and lysosomes.

Mycobacterium tuberculosis phagosomes exhibit altered calmodulin-dependent signal transduction: contribution to inhibition of phagosome-lysosome fusion and intracellular survival in human macrophages

Mycobacterium tuberculosis successfully parasitizes macrophages by disrupting the maturation of its phagosome, creating an intracellular compartment with endosomal rather than lysosomal characteristics. We have recently demonstrated that live M. tuberculosis infect human macrophages in the absence of an increase in cytosolic Ca(2+) ([Ca(2+)](c)), which correlates with inhibition of phagosome-lysosome fusion and intracellular viability. In contrast, killed M. tuberculosis induces an elevation in [Ca(2+)](c) that is coupled to phagosome-lysosome fusion. We tested the hypothesis that defective activation of the Ca(2+)-dependent effector proteins calmodulin (CaM) and CaM-dependent protein kinase II (CaMKII) contributes to the intracellular pathogenesis of tuberculosis. Phagosomes containing live M. tuberculosis exhibited decreased levels of CaM and the activated form of CaMKII compared with phagosomes encompassing killed tubercle bacilli. Furthermore, ionophore-induced elevations in [Ca(2+)](c) resulted in recruitment of CaM and activation of CaMKII on phagosomes containing live M. tuberculosis. Specific inhibitors of CaM or CaMKII blocked Ca(2+) ionophore-induced phagosomal maturation and enhanced the bacilli's intracellular viability. These results demonstrate a novel role for CaM and CaMKII in the regulation of phagosome-lysosome fusion and suggest that defective activation of these Ca(2+)-activated signaling components contributes to the successful parasitism of human macrophages by M. tuberculosis.

Recycling cell surface glycoproteins undergo limited oligosaccharide reprocessing in LEC1 mutant Chinese hamster ovary cells

The ability of particular cell surface glycoproteins to recycle and become exposed to individual Golgi enzymes has been demonstrated. This study was designed to determine whether endocytic trafficking includes significant reentry into the overall oligosaccharide processing pathway. The Lec1 mutant of Chinese hamster ovary (CHO) cells lack N -acetylglucosaminyltransferase I (GlcNAc-TI) activity resulting in surface expression of incompletely processed Man5GlcNAc2 N -linked oligosaccharides. An oligosaccharide tracer was created by exoglycosylation of cell surface glycoproteins with purified porcine GlcNAc-TI and UDP-[3H]GlcNAc. Upon reculturing, all cell surface glycoproteins that acquired [3H]GlcNAc were acted upon by intracellular mannosidase II, the next enzyme in the Golgi processing pathway of complex N -linked oligosaccharides (t1/2= 3-4 h). That all radiolabeled cell surface glycoproteins were included in this endocytic pathway indicates a common intracellular compartment into which endocytosed cell surface glycoproteins return. Significantly, no evidence was found for continued oligosaccharide processing consistent with transit through the latter cisternae of the Golgi apparatus. These data indicate that, although recycling plasma membrane glycoproteins can be reexposed to individual Golgi-derived enzymes, significant reentry into the overall contiguous processing pathway is not evident.

A novel fluorescence-activated cell sorter-based screen for yeast endocytosis mutants identifies a yeast homologue of mammalian eps15

A complete understanding of the molecular mechanisms of endocytosis requires the discovery and characterization of the protein machinery that mediates this aspect of membrane trafficking. A novel genetic screen was used to identify yeast mutants defective in internalization of bulk lipid. The fluorescent lipophilic styryl dye FM4-64 was used in conjunction with FACS to enrich for yeast mutants that exhibit internalization defects. Detailed characterization of two of these mutants, dim1-1 and dim2-1, revealed defects in the endocytic pathway. Like other yeast endocytosis mutants, the temperature-sensitive dim mutant were unable to endocytose FM4-64 or radiolabeled alpha-factor as efficiently as wild-type cells. In addition, double mutants with either dim1-delta or dim2-1 and the endocytosis mutants end4-1 or act1-1 displayed synthetic growth defects, indicating that the DIM gene products function in a common or parallel endocytic pathway. Complementation cloning of the DIM genes revealed identity of DIM1 to SHE4 and DIM2 to PAN1. Pan1p shares homology with the mammalian clathrin adaptor-associated protein, eps15. Both proteins contain multiple EH (eps15 homology) domains, a motif proposed to mediate protein-protein interactions. Phalloidin labeling of filamentous actin revealed profound defects in the actin cytoskeleton in both dim mutants. EM analysis revealed that the dim mutants accumulate vesicles and tubulo-vesicular structures reminiscent of mammalian early endosomes. In addition, the accumulation of novel plasma membrane invaginations where endocytosis is likely to occur were visualized in the mutants by electron microscopy using cationized ferritin as a marker for the endocytic pathway. This new screening strategy demonstrates a role for She4p and Pan1p in endocytosis, and provides a new general method for the identification of additional endocytosis mutants.

Localization of the small GTP-binding protein rab1p to early compartments of the secretory pathway

We have studied the localization of the small GTPase rab1p in different cell types using polyclonal antibodies prepared against the rab1A isoform of the protein. Immunofluorescence microscopy of normal rat kidney (NRK) and mouse myeloma cells showed the association of the protein with the Golgi complex and peripheral sites where it colocalized with p58, a pre- and cis-Golgi marker protein. Rab1p and p58 also had similar distributions in membrane fractions derived from rat pancreas microsomes. Both were concentrated in two intermediate density subfractions between the rough endoplasmic reticulum and trans-Golgi, whereas rab6p, previously localized to middle and trans-Golgi, was enriched in the light density trans-Golgi fraction. Immunoperoxidase electron microscopy of NRK and myeloma cells revealed the association of rab1p with 1–2 cisternae, vacuolar, and tubulovesicular membranes in the cis-Golgi region. The rab1p-specific staining typically covered the entire lateral surface of the cisternae but, in weakly stained cells, local labeling between closely opposed membranes could also be seen. The rab1p-positive pre-Golgi compartment had a predominantly tubulovesicular appearance in NRK cells whereas in myeloma cells it consisted of vacuoles surrounded by rab1p-positive vesicles and tubules of heterogeneous size. In both cell types the rough ER cisternae and the nuclear envelope contained negligible labeling and no continuities between these and the rab1p-positive membranes were observed. In addition, in myeloma cells the smooth ER subcompartment, containing endogenous retrovirus particles, was devoid of rab1p-labeling. These results indicate that the pre-Golgi (intermediate) compartment consists of different membrane domains and its morphology can vary considerably between different cell types. Further, they suggest that the recruitment of rab1p to membranes occurs predominantly in a post-ER location and that the protein functions in targeting/fusion events within the pre- and cis-Golgi membranes.

Coated vesicles are implicated in the post-fusion retrieval of the membrane of rat atrial secretory granules

Using an in situ tannic acid perfusion technique, this study presents evidence that the removal of membrane components from the rat atrial secretory granule membrane after granule exocytosis is mediated by coated vesicles. When tannic acid is used to arrest the post-fusion stages of granule release, coated pit formation occurs on granule membrane, which, although continuous with the sarcolemma, is easily recognised by the membrane omega profile and the continued presence of the granule core. Tannic acid perfusion, before aldehyde fixation, allows a degree of continued cell function, and granule fusions can persist after tannic acid has reached the cell. This results in an increase in the numbers of fusion profiles and the appearance of coated pits on granule membrane at these sites. The proportion of granules with coats increases with perfusion time, suggesting that endocytotic, as well exocytotic events, may be arrested by the action of tannic acid. Coated vesicles are also involved at earlier stages of the release pathway. In other types of secretory system this is considered to represent recycling of membrane proteins as part of the maturation process of the granule. Although arrested granules exhibiting this clathrin coat could have had the coat prior to fusion, as part of the maturation process, our results show that it is more likely to represent a second stage of membrane protein recycling; the postfusion reclamation of proteins from the sarcolemma. This facet of the tannic acid perfusion procedure suggests a general method for quantifying coated pit formation during secretory granule release.

Low density lipoprotein receptor and cation-independent mannose 6-phosphate receptor are transported from the cell surface to the Golgi apparatus at equal rates in PC12 cells

Efficient transport of cell surface glycoproteins to the Golgi apparatus has been previously demonstrated for a limited number of proteins, and has been proposed to require selective sorting in the endocytic pathway after internalization. We have studied the endocytic fate of several glycoproteins that accumulate in different organelles in a variant clone of PC12, a regulated secretory cell line. The cation-independent mannose 6-phosphate receptor and the low density lipoprotein receptor, both rapidly internalized from the cell surface, and the synaptic vesicle membrane protein synaptophysin, were transported to the Golgi apparatus with equivalent, nonlinear kinetics. Transport to the Golgi apparatus (t1/2 = 2.5-3.0 h) was several times faster than turnover of these proteins (t1/2 greater than or equal to 20 h), indicating that transport of these proteins to the Golgi apparatus occurred on average several times for each protein. In contrast, Thy-1, a protein anchored in the membrane by a glycosylphosphoinositide group, was internalized and transported to the Golgi apparatus more slowly than the three transmembrane proteins. Since each of the transmembrane proteins studied showed the same t1/2 for transport to the Golgi apparatus, we conclude that transport of these proteins from the cell surface to the Golgi apparatus does not require sorting information specific to any one of these proteins. These results suggest that one of the functions of late endosomes is constitutive recycling of cell surface receptors through the Golgi apparatus if they fail to recycle to the cell surface directly from early endosomes, and that the late endosome recycling pathway is followed frequently by many rapidly internalized proteins.

The absorption and transport of lipids by the small intestine

Dietary lipid provides as much as 40% of the caloric intake in the Western diet. Triacylglycerol is the main dietary fat. The human small intestine is also presented daily with 11-12 g of phospholipid, predominantly phosphatidylcholine. The predominant sterol in the Western diet is cholesterol, which is derived from animal fat. Plant sterols account for up to 20-25% of total dietary sterol. This paper reviews our current understanding of the process and the factors that regulate the absorption and transport of different dietary lipids by the human small intestine.

In vitro endocytosis of benign and malignant human bone marrow plasma cells

We report ultrastructural evidence of the phagocytic potential of plasma cells and myeloma cells. The incubation of plasma cells and myeloma cells in vitro with horseradish peroxidase (HRP) and cationized ferritin (CF) allows the tracing of fluid-phase and receptor-mediated pathways. Surface-bound ligands (CF) and solutes (HRP) taken up in primary pinocytic vesicles are internalized to the endosomal compartment. After 1 hr of incubation, CF was found not only in plasma cells but also in myeloma cells. Reaction products of HRP were observed only in myeloma cells. In myeloma cells, however, HRP was located only in the lysosomal system, whereas CF was present within membrane cisternae as well as within lysosomes. These myeloma cells morphologically produced interleukin-6 (IL-6).

Retrograde trafficking of tracer protein by the internal ovarian epithelium in gravid goodeid teleosts

Gravid goodeid females harbor embryos in a preformed ovarian cavity for prolonged periods of gestation. Various nutrients for embryonic growth are provided by the internal ovarian epithelium (IOE). Its cells flatten during late stages of gestation and form an attenuated layer of cytoplasm covering a dense network of protruding capillaries, with the nuclear domains mostly recessing between the vascular meshes. The IOE in both Xenotoca eiseni and Girardinichthys viviparus exhibit morphological features associated with vesicular transport of macromolecules. The amounts of rough endoplasmic reticulum in the IOE cells seem insufficient to effectively synthesise proteinaceous secretions. Apparently, it rather serves as a transit route for serum-derived products. Cationized ferritin (CF) was injected into the ovarian cavity of gravid females. The electrostatic ligand spotwise attached to the luminal surface of the IOE and gained access by adsorptive micropinocytosis. Many tracer molecules were sequestered into lysosome-like vacuoles that became increasingly swollen after prolonged incubation intervals. In addition, CF traversed the IOE within small vesicles. At the basal pole of the cells the contents of transcytotic vesicles were evacuated, and localization of small CF-clusters was regularly in the basement lamina, in the underlying connective tissue, in vacuoles within migrant cells, in vesicular compartments of the capillary endothelia, in capillary lumina, and in intravascular leucocytes. Tracer molecules were never observed to enter stacked Golgi cisternae. Since the cationic marker probably follows retrograde pathways of the protein secretion, the experimental data support the morphologically derived conclusions that postulate a major role for the IOE in transepithelial transport.

The recycling of a secretory granule membrane protein

We have used N-hydroxysuccinimido-d-biotin as a reagent for labeling proteins exposed at the surface of cultured bovine adrenal chromaffin cells during Ba2+-stimulated secretion. A specific secretory granule membrane constituent, dopamine-beta-hydroxylase (DBH), has been investigated using immunoprecipitation followed by electrophoresis. Within 30 min of stimulation, exposed DBH had been cleared from the cell surface. Nevertheless, quantitation of labeled DBH using [125I] streptavidin suggested that it remained undegraded over a period of 24 h, a time during which secretory granule stores of catecholamines were being replenished. Subcellular fractionation of the cultured cells suggested that, after 3 or 4 h, the biotinylated DBH, which was still membrane-bound, was located in particulate material that also contained cytochrome b561, another major secretory granule membrane component.

Rapid fragmentation and reorganization of Golgi membranes during frustrated phagocytosis of immobile immune complexes by macrophages

The authors have observed the rapid reorganization of the cellular membranes of macrophages during Fc receptor-mediated frustrated phagocytosis of immune complex-coated surfaces. As the macrophages spread, large, clear basal vacuoles and anastamosing tubules were formed, occasionally contiguous with the adherent surface. Coated vesicles also were observed. This process was accompanied by a rapid reorganization of the Golgi complex region of the macrophages, which was observed using trimetaphosphatase histochemistry and an antibody to a Golgi membrane antigen as markers. On contact of the macrophages with the immune complexes, the Golgi complexes, which were tightly clustered around the centrioles, dispersed into vesicles and reorganized near the basal surface. The Golgi cisternae swelled, fragmented, and decreased in number. Golgi membrane antigen was found in the large basal vacuoles and also associated with the adherent basal surface of the macrophages. This indicates that the Golgi complexes were reorganized, in part, by a direct recruitment of their membranes to the increasing basal surface area of the spreading macrophages. The changes in the structure of the Golgi complexes were reversible; by 2 hours, the complexes had recovered their normal organization, with an accompanying decrease in the number of large basal vacuoles. These data suggest that the dynamic interrelationship among the Golgi membranes, intracellular vacuoles, and the plasma membrane can be perturbed by membrane spreading on a nonphagocytosable surface.

Chitosan-colloidal gold complexes as polycationic probes for the detection of anionic sites by transmission and scanning electron microscopy

A new cationic colloidal gold complex has been developed for ultrastructural localization of cell surface anionic sites by transmission and scanning electron microscopy. The marker is prepared by labelling gold particles of suitable sizes (6 to 70 nm in diameter) with chitosan, a polymer of beta (1----4)-linked D-glucosamine. Using human red blood cells as a model, chitosan-gold complexes were shown to be specific for anionic sites and at pH 2 for sialic acid residues. The binding capacity of complexes of different sizes with carboxymethyl and phosphorylated celluloses was examined as a function of pH and ionic strength. The results indicated that these complexes can be used under acidic conditions as well as in physiological buffers. The complexes were further tested by transmission and scanning electron microscopy in detecting anionic sites on cells of various origins such as Escherichia coli, Lactobacillus maltaromicus, Lactobacillus reuteri, Saccharomyces cerevisiae, Saccharomyces rouxii, Schizosaccharomyces pombe, Fusarium oxysporum, Catharantus roseus.

Acid phosphatase as a selective marker for a class of small sensory ganglion cells in several mammals: spinal cord distribution, histochemical properties, and relation to fluoride-resistant acid phosphatase (FRAP) of rodents

Fluoride-resistant acid phosphatase (FRAP) activity as characterized in rat and mouse was studied in sensory ganglion and spinal cord of several mammals, using both the Gomori lead-ion capture and azo-dye coupling methods. FRAP was specifically localized to small- and medium-diameter primary afferent neurons and inner substantia gelatinosa of all nonrodent animals studied, including rabbit, cat, dog, monkey, cow, and human. In rabbit, sciatic nerve transection resulted in depletion of enzymatic activity in ipsilateral spinal cord dorsal horn in a pattern corresponding to the distribution of central terminals of the nerve. Further analysis of the substrate specificity and pH dependence of FRAP was carried out primarily in rat sensory ganglion and spinal cord; the enzyme was found to hydrolyze a wide variety of phosphomonoesters in a relatively nonselective manner at both pH 5 and pH 7, including 5'-nucleotides, phosphorylated amino acids, and several exogenous compounds. The visualization of FRAP-like activity in several nonrodent species is discussed with reference to previous work indicating its presence only in mouse and rat. Technical factors are considered that limit the applicability of the lead-ion histochemical method in demonstration of FRAP and in efforts at functional characterization of the enzyme, especially in light of its ability to hydrolyze a broad spectrum of substrates over a wide pH range. Alternative interpretations of the expression of acid phosphatase activity in a select class of small sensory ganglion cells are suggested, including several possible non-synaptic roles of FRAP in the peripheral nervous system.

Relations between plasma membrane and lysosomal membrane. 1. Fate of covalently labelled plasma membrane protein

To quantify the kinetics of the plasma membrane flow into lysosomes, we covalently labelled at 4 degrees C the pericellular membrane of rat fibroblasts and followed label redistribution to the lysosomal membrane using purified lysosomal preparations. The polypeptides were, either labelled with 125I by the lactoperoxidase procedure, or conjugated to [3H]peroxidase using bisdiazobenzidine as a bifunctional reagent. Both labels were initially bound to plasma membrane, as indicated by their equilibrium density in sucrose or Percoll gradients and their displacement by digitonin, as well as by electron microscopy. Upon cell incubation at 37 degrees C, both covalent labels were lost from cells with diphasic kinetics: a minor component (35% of cell-associated labels) was rapidly released (half-life less than 1 h), and most label (65%) was released slowly (half-life was 20 h for incorporated 125I and 27 h for 3H). Immediately after labelling up to 30 h after incubation at 37 degrees C, the patterns of 125I-polypeptides quantified by autoradiography after SDS-PAGE were indistinguishable, indicating no preferential turnover for the major plasma membrane polypeptides. The redistribution of both labels to lysosomes was next quantified by cell fractionation. At equilibrium (between 6 and 25 h of cell incubation) 2-4% of cell-associated 125I label was recovered with the purified lysosomal membranes. By contrast, when 3H-labelled cells were incubated for 16 h, most of the label codistributed with lysosomes. However, only 6% of cell-associated 3H was bound to lysosomal membrane. These results indicate that in cultured rat fibroblasts, a minor fraction of plasma membrane polypeptides becomes associated with the lysosomal membrane and is constantly equilibrated by membrane traffic.

Antibodies to rat pancreas Golgi subfractions: identification of a 58-kD cis-Golgi protein

A 58-kD cis-Golgi protein has been identified by generating polyclonal antibodies against heavy (cis) Golgi subfractions. Total microsomes isolated from rat pancreatic homogenates were subfractionated to yield a rough microsomal fraction (B1) and three smooth membrane subfractions (B2-B4) enriched in cis-, middle, and trans-Golgi elements, respectively. The heavy (cis) subfraction, B2 (d = 1.17 g/ml), was fractionated by Triton X-114 phase separation, and the proteins recovered in the detergent phase were used to immunize rabbits. One of the anti-B2 antibodies obtained gave a "Golgi"-staining pattern when screened by immunofluorescence on normal rat kidney cells and mouse RPC 5.4 myeloma cells. In rat pancreatic exocrine cells the antibody reacted with the plasmalemma as well as elements in the Golgi region. By immunoelectron microscopy, the antigen recognized by anti-B2 IgG was found to be restricted to cis-Golgi elements in myeloma cells where it was concentrated in the fenestrated cis-most cisterna and in some of the tubules and vesicles located along the cis face of the Golgi complex. By immunoprecipitation and immunoblotting, the anti-B2 IgG exclusively recognized a 58-kD protein in myeloma cells. The anti-B2 IgG reacted with several proteins in solubilized pancreatic B2 membranes, including a 58-kD protein, but affinity-purified anti-58-kD IgG reacted exclusively with the 58-kD protein. These results suggest that the 58-kD protein is a specific component of cis-Golgi membranes.

Endocytosis of native and cationized ferritin by intralobular duct cells of the rat parotid gland

The ability of the intralobular ducts of the rat parotid gland to take up protein from the lumen was examined after retrograde infusion of native and cationized ferritin. At high concentrations (3-10 mg/ml), cells of both intercalated- and striated ducts avidly internalized the tracers. No differences were noted in the mode of uptake or fate of native or cationized ferritin. Large, apical ferritin-containing vacuoles up to 5 microns in size were present in cells of the intercalated ducts after infusion for 15 min. Small, smooth-surfaced spherical or flattened vesicles and tubules containing ferritin were also observed, often in association with the large vacuoles. Ferritin uptake increased with increasing infusion time, up to 1 h. Uptake by the striated ducts was less consistent than by the intercalated ducts, and occurred mainly in small vesicles and tubules. Secondary lysosomes became labeled with ferritin in both cell types. Ferritin was not observed in the Golgi saccules, nor was it discharged from the cells at the basolateral surfaces. At low concentrations (0.3-1 mg/ml), uptake was reduced, especially by cells of intercalated ducts, and differences were noted in the behavior of the two tracers. Cationized ferritin was internalized mainly into vesicles and tubules of cells of striated ducts; little uptake of native ferritin occurred at low concentrations. These results demonstrate that the ductal cells of the salivary glands are capable of luminal endocytosis of foreign proteins. They also suggest that in addition to modifying the primary saliva by electrolyte reabsorption and secretion, and secretion of various glycoproteins, the ductal cells are able to reabsorb proteins secreted by the acinar cells.

Delivery of internalized ricin from endosomes to cisternal Golgi elements is a discontinuous, temperature-sensitive process

Galactose-terminating membrane glycoproteins and glycolipids on two established human breast carcinoma cell lines were tagged at 4 degrees C with a ricin-horseradish peroxidase conjugate (Ri-HRP). The cells were then incubated for various periods of time at 37 or 18 degrees C. After fixation and diaminobenzidine cytochemistry, the compartments reached by Ri-HRP were studied by analyzing thin serial sections. In both cell types a highly pleomorphic endosomal system comprising vacuolar elements as well as smaller, sometimes branched, tubular elements (tubular endosomes) was revealed at both 37 and 18 degrees C. At 37 degrees C Ri-HRP was consistently observed in flattened cisterns of the Golgi region in 30-40% of the Golgi complexes examined after 30-60 min of incubation. However, no Ri-HRP reached such Golgi elements at 18 degrees C, even after incubation for 180 min. Moreover, at 18 degrees C the ability of ricin to inhibit protein synthesis was virtually abolished, whereas the effect of diphtheria toxin was reduced much less. Following incubation with a monovalent transferrin-HRP conjugate or with unconjugated HRP, no labeling of cisternal Golgi elements was detected. These data indicate that delivery of galactose-terminating membrane molecules from endosomes to the Golgi complex is a discontinuous, temperature-sensitive process and that this process may be required for optimal ricin A-chain translocation.

Transferrin receptors recycle to cis and middle as well as trans Golgi cisternae in Ig-secreting myeloma cells

The recycling itinerary of plasma membrane transferrin receptors (TFR) was charted in IgG-secreting mouse myeloma cells (RPC 5.4) by tagging surface receptors with either bound anti-transferrin receptor antibodies (anti-TFR) or Fab fragments thereof and determining the intracellular destinations of the tagged receptors by immunocytochemistry. By immunofluorescence, TFR tagged with either probe were seen to be rapidly internalized and translocated from the cell surface to the juxtanuclear (Golgi) region. When localized by immunoperoxidase procedures at the electron microscopic level, the anti-TFR-labeled receptors were detected in all cisternae (cis, middle, and trans) of the Golgi stacks as well as in endosomes and trans Golgi reticular elements. There was no difference in the routing of TFR tagged with monovalent Fab and those tagged with divalent IgG. Tagged receptors were detected in Golgi stacks of approximately 50% of the cells analyzed. The position of the labeled cisternae within a given stack was found to be quite variable with cis and middle cisternae more often labeled at 5 min and trans cisternae at 30 min of antibody uptake. The finding that recycling plasmalemmal TFR can visit all or most Golgi subcompartments raises the likely possibility that any Golgi-associated posttranslational modification can occur during recycling as well as during the initial biosynthesis of plasmalemma receptors and other membrane proteins.

Membrane traffic in animal cells: cellular glycoproteins return to the site of Golgi mannosidase I

The recycling of cellular glycoproteins to the site of Golgi mannosidase I, an enzyme of asparagine-linked oligosaccharide synthesis, was studied in K562 human erythroleukemia cells. Cells were metabolically labeled in the presence of deoxymannojirimycin, a reversible inhibitor of Golgi mannosidase I. This generates glycoproteins with immature oligosaccharides in their normal locations. Transport to the mannosidase I compartment was then assessed by testing for the conversion of oligosaccharides into mature forms during reculture without deoxymannojirimycin. Transferrin receptor (TfR) was acted on by mannosidase I during reculture, suggesting that it returned to the region of the Golgi complex where this enzyme resides. The slow rate of this transport (t1/2 greater than 6 h) implies that it is probably different than TfR movement during transferrin internalization (t1/2 = 10-20 min) and TfR transport to the sialyltransferase compartment in the Golgi complex (t1/2 = 2-3 h) (Snider, M. D., and O. C. Rogers, 1985, J. Cell Biol., 100:826-834). The total cell glycoprotein pool was also transported to the mannosidase I compartment with a half-time of 4 h. Because this transport is 5-10 times faster than the rate of de novo glycoprotein synthesis in these cells, it is likely that most of the glycoprotein traffic through the Golgi complex is composed of recycling molecules.

Alterations in plasma membrane lipid organization during lymphocyte differentiation

The fluorescent probe merocyanine 540, which binds preferentially to bilayers in which the lipids are loosely packed, was used to investigate changes in the organization of the lipids of the lymphocyte plasma membrane during primary and secondary lymphopoiesis. When mouse thymocytes were incubated with the dye, most immature cells stained, while most mature cells, about to enter the peripheral circulation, did not. Similarly, mature lymphocytes from both mouse and human peripheral blood did not stain, but these same cells did when activated by in vitro mitogenic stimulation. Freshly isolated splenic lymphocytes, presumably activated in vivo by antigen, also bound merocyanine 540, but after 48 hours of culture in the absence of stimulus they displayed only a low affinity for the dye, a phenotype that reverted to a high affinity upon mitogenic stimulation. These results suggest that changes in the organization of the lipids of the plasma membrane take place during lymphocyte differentiation: viz., immature cells possess a disordered membrane that becomes increasingly ordered as the cells mature and enter the peripheral circulation; then, upon antigen-induced differentiation, the plasma membrane again becomes disordered. These lipid organization changes are discussed in the context of their possible role in the regulation of lymphocyte circulation via intercellular interactions between lymphocytes and cells of the reticuloendothelial system.

Study of the transit of an integral membrane protein from secretory granules through the plasma membrane of secreting rat basophilic leukemia cells using a specific monoclonal antibody

The monoclonal antibody 5G10 reacted specifically with an 80-kD integral membrane protein in rat basophilic leukemia (RBL) cells. Immunofluorescence microscopy studies of RBL cells, fixed and permeabilized, revealed that the 80-kD protein was located in the membrane of cytoplasmic vesicles. The vesicles were identified as secretory granules by their content in immunoreactive serotonin. Expression of the 5G10 antigen on the surface of unstimulated RBL cells was low. However, RBL cells stimulated to secrete with anti-dinitrophenyl IgE followed by dinitrophenyl-bovine serum albumin or with the Ca2+ ionophore A-23187 displayed an increased expression of the antigen on their surface. Surface exposure of the 5G10 antigen was maximal at 5 min after stimulation of secretion. Removal of dinitrophenyl-bovine serum albumin from the incubation medium resulted in internalization of 50% of the antigen within 10 min.

Routing of internalized ricin and ricin conjugates to the Golgi complex

Receptor-mediated endocytosis and intracellular routing of native ricin, and of ricin conjugated to colloidal gold (Ri-Au) and to horseradish peroxidase (Ri-HRP), have been studied in cultured MCF-7 and Vero cells by electron microscopical techniques including serial section analysis. Both native ricin, as demonstrated by immunoperoxidase cytochemistry, and the ricin conjugates were internalized via a common coated pit-coated vesicle pathway to reach vacuolar and tubulo-vesicular portions of the endosomal system. In addition, native ricin and a purified monovalent fraction of Ri-HRP reached distinct Golgi cisterns, whereas Ri-Au and polyvalent Ri-HRP did not. The results delineate intracellular routing of native ricin and compare it with the routing of different ricin conjugates. Moreover, our study shows that conjugates of a particular ligand (ricin) and various probes (e.g., gold and peroxidase), may be handled differently by cells. Sorting apparently takes place in the endosomal system, allowing some but not other molecules to reach Golgi elements. This sorting seems to depend on the valency of the ricin conjugate.

Evidence for a decreased membrane recycling in the cells of renal proximal tubules exposed to high concentrations of ferritin

The present study was performed to investigate whether membrane recycling via the dense apical tubules in cells of renal proximal tubules could be modified after exposure to large amounts of cationized ferritin. Proximal tubules in the rat kidney were microinfused in vivo with cationized ferritin for 10 or 30 min and then fixed with glutaraldehyde by microinfusion, or proximal tubules were microinfused with ferritin for 30 min and then fixed 2 h thereafter. The tubules were processed for electron microscopy, and the surface density and the volume density of the different cell organelles involved in endocytosis were determined by morphometry. The morphometric analyses showed that after loading of the endocytic vesicles with ferritin the surface density of dense apical tubules decreased to about 50% of the original value. However, 2 h later when ferritin had accumulated in the lysosomes the surface density of dense apical tubules had returned to control values. Furthermore, cationized ferritin was virtually absent from the Golgi region, indicating that the Golgi apparatus in these cells does not participate in membrane recycling. In conclusion, the present study shows that membrane recycling in renal proximal tubule cells can in part be inhibited by loading the endocytic vacuoles with ferritin.

The effects of mucus on the binding of cationized ferritin by human and animal gastrointestinal epithelium

Human gallbladder and gastric epithelial cells are normally covered with a layer of mucus. When specimens were exposed to cationized ferritin (CF) in vitro, they did not regularly bind nor internalise it. If the tissues were first exposed to the mucolytic agents cysteamine or pepsin, then the gallbladder epithelium readily bound CF and the gastric epithelium irregularly. The in vivo binding of CF by guinea pig gallbladder could be abolished by the induction of mucous hypersecretion by the antibiotic lincomycin. The removal of the mucus by mucolytic agents restored the binding of CF. The irregular binding of CF by gastric mucosa after the use of mucolytic agents suggests other factors may be at play.

Intracellular pathways of endocytosed tracers in Leydig cells of the rat

The endocytic activity of Leydig cells was examined by electron microscopy following the injection, into the interstitial space, of tracers used to examine fluid-phase endocytosis, ie, native ferritin and horseradish peroxidase-colloidal gold (horseradish peroxidase-gold), and adsorptive endocytosis, ie, cationic ferritin. At 5 minutes after injection, native ferritin or horseradish peroxidase-gold was present in the interstitial space and free in the lumen of large endocytic vesicles forming at the cell surface. At 15 minutes, these tracers appeared in the matrix of pale multivesicular bodies, while at 30 minutes and 1 hour, the matrix of dense multivesicular bodies became labeled. Beginning at 1 hour, dense membrane-delimited bodies identified cytochemically as lysosomes were labeled. In the case of cationic ferritin, two distinct pathways were taken. In one pathway, cationic ferritin was observed 5 minutes after injection bound to the plasma membrane of Leydig cells and to the membrane of small and large endocytic vesicles. At subsequent time intervals, cationic ferritin appeared consecutively in pale, dense multivesicular bodies and lysosomes. In a second pathway, cationic ferritin was observed at 5, 15, and 30 minutes bound to the membrane of vesicles of intermediate size seen near the cell surface. At 1, 1 1/2 and 2 hours, cationic ferritin-containing intermediate vesicles appeared in increasing number in the Golgi region. However, cationic ferritin was never observed in the Golgi saccules themselves. At later time intervals (3-6 hours), intermediate vesicles labeled with cationic ferritin progressively disappeared from the Golgi region and the cell. Thus in Leydig cells, while fluid-phase tracers reached lysosomes exclusively, cationic ferritin, a tracer of adsorptive endocytosis, not only reached the lysosomes, but was also carried by the intermediate vesicles to the Golgi region of the cell.

Intracellular movement of cell surface receptors after endocytosis: resialylation of asialo-transferrin receptor in human erythroleukemia cells

The intracellular movement of cell surface transferrin receptor (TfR) after internalization was studied in K562 cultured human erythroleukemia cells. The sialic acid residues of the TfR glycoprotein were used to monitor transport to the Golgi complex, the site of sialyltransferases. Surface-labeled cells were treated with neuraminidase, and readdition of sialic acid residues, monitored by isoelectric focusing of immunoprecipitated TfR, was used to assess the movement of receptor to sialyltransferase-containing compartments. Asialo-TfR was resialylated by the cells with a half-time of 2-3 h. Resialylation occurred in an intracellular organelle, since it was inhibited by treatments that allow internalization of surface components but block transfer out of the endosomal compartment. Moreover, roughly half of the resialylated molecules were cleaved when cells were retreated with neuraminidase after culturing, indicating that this fraction of the molecules had returned to the cell surface. These results suggest that TfR is transported from the cell surface to the Golgi complex, the intracellular site of sialyltransferases, and then returns to the cell surface. This pathway, which has not been previously described for a cell surface receptor, may be different from the route followed by TfR in iron uptake, since reported rates of transferrin uptake and release are significantly more rapid than the resialylation of asialo-TfR.

Antibodies against a lysosomal membrane antigen recognize a prelysosomal compartment involved in the endocytic pathway in cultured prolactin cells

Antibodies against a lysosomal membrane antigen (A-Ly-M) have recently been obtained and characterized (Reggio, H., D. Bainton, E. Harms, E. Coudrier, and D. Louvard, 1984, J. Cell Biol., 99:1511-1526). They recognize a 100,000-mol-wt antigen immunologically related to a purified [H+,K+]ATPase from pig gastric mucosa. In the present study, we have localized this antigen during adsorptive endocytosis in rat prolactin cells in culture using cationized ferritin (CF) as a tracer. CF was rapidly internalized (after 5 min) in coated pits and vesicles that were labeled by antibodies against clathrin. The tracer was then delivered (after 15 min) to vacuoles and multivesicular bodies. These structures were labeled with A-Ly-M. These organelles were devoid of acid phosphatase activity. At later stages (after 30 min) CF was observed within larger structures that were strongly stained by A-Ly-M and displayed a strong acid phosphatase activity. These findings clearly indicate that A-Ly-M react with prelysosomal and lysosomal compartments involved in the endocytic pathway in cultured prolactin cells. The membrane of these structures therefore contains antigenic determinant(s) related to the 100,000-mol-wt polypeptide. Our results suggest that the prelysosomal structure stained by A-Ly-M may represent in GH3 cells the acidic prelysosomal compartment recently described in the early steps of endocytosis in other cell types (Tycko, B., and F. R. Maxfield, 1982, Cell, 28:643-651).

Assembled and unassembled pools of clathrin: a quantitative study using an enzyme immunoassay

Using polyclonal antibodies raised against clathrin, we have developed an enzyme-linked immunoassay that can specifically measure the quantity of clathrin in crude cell extracts. We found that the quantity (weight percent of total protein) of clathrin was similar in cell types that exhibit large differences in their levels of endocytosis and exocytosis (lymphoid cells, 0.11%; liver cells, 0.07%, fibroblasts, 0.18%; myeloma cells, 0.16%). However, the quantity of clathrin was found to be significantly higher in brain cortex (0.75%). Cellular clathrin was separated by high-speed centrifugation into two fractions: an unassembled form present in high-speed supernatants and an assembled form (clathrin coats) present in the pellets. We show that the fraction of clathrin in the unassembled state varies considerably depending on the cell type studied (14% in brain cortex to 70% in lymphocytes). Our data support the view that the amount of clathrin (relative to total cell protein) in eucaryotic cells is not related to the extent of receptor-mediated endocytosis and intracellular membrane traffic. However, the fraction of assembled clathrin seems to be higher in endocytically and/or exocytically active cells.

The presence and orientation of ecto-5'-nucleotidase in rat liver lysosomes

Purified rat liver lysosomes contained 5'-nucleotidase activity which was 92 +/- 2% [4]latent. This latency was lost in response to a permeant sugar at a similar rate to that of the lysosomal marker enzyme beta-N-acetylglucosaminidase indicating that the 5'-nucleotidase was genuinely located in the lysosome and not a plasma membrane contaminant. Lysosomal 5'-nucleotidase exhibited the following properties characteristic of ecto-5'-nucleotidase inhibition by specific polyclonal antibodies: binding to a monoclonal antibody; inhibition by 1 mmol/1 alpha beta-methylene ADP; immunoreactive subunits of 70 and 38 kDa. Lysosomes in addition contained immunoreactive species of intermediate molecular mass.

Basolateral endocytosis of protein in isolated perfused proximal tubules

Luminal uptake and degradation of protein in proximal tubules is well documented. However, abluminal uptake has only been demonstrated in a few species and probably only amounts to a few percent of luminal absorption. To investigate this absorptive pathway, isolated perfused proximal tubules from rabbit kidney were exposed to either cationized ferritin or horseradish peroxidase in the bath for 30 min. The tubules were then fixed and processed for electron microscopy. Peroxidase and small amounts of ferritin were found in the intercellular spaces, in endocytic vesicles located in the abluminal part of the cells and in multivesicular bodies. No tracer was found in the lumina or in the apical part of the cells. The tubules were ultrastructurally intact thus excluding the possibility that the proteins were absorbed via the luminal endocytic pathway or as a result of damaged cell membranes. In conclusion, this study presents evidence that ferritin and peroxidase can be absorbed via the basolateral membranes in rabbit proximal tubules.

Soluble and immobilized anti-Ig antibodies in the regulation of LPS-induced lymphoblasts

Anti-immunoglobulin (anti-Ig) causes suppression of secretion of immunoglobulin by LPS-activated pig B lymphoblasts. The cellular level at which anti-Ig influences immunoglobulin secretion has been investigated, using soluble anti-Ig which enters B cells, and anti-Ig immobilized onto acrylamide bead or plastic surfaces which can act only at the B-cell surface. Suppression of secretion only occurred with soluble anti-Ig, indicating that the intracellular processing of antibody after its complexing on the cell surface was necessary for suppression to occur. Immobilized anti-Ig acted as effectively as soluble antibody in activation of resting B cells into mitosis, showing that the activating signal of anti-Ig is received at the cell surface. Electron microscopy has shown that the block to secretion after soluble anti-Ig resulted from the accumulation of smooth membrane-bounded intracellular vesicles which, by immunofluorescence, contained immunoglobulin. The formation of vesicles was intimately associated with the intracellular localization of 125I-labelled anti-Ig which was used to follow cellular processing of anti-Ig.

Endocytosis of cationized ferritin by coated vesicles of soybean protoplasts

Soybean (Glycine max (L.) Merr.) protoplasts have been surface-labelled with cationized ferritin, and the fate of the label has been followed ultrastructurally. Endocytosis of the label occurs via the coated-membrane system. The pathway followed by the label, once it has been taken into the interior of the protoplast, appears to be similar to that found during receptor-mediated endocytosis in animal cells. Cationized ferritin is first seen in coated vesicles but rapidly appears in smooth vesicles. Labelled, partially coated vesicles are occasionally observed, indicating that the smooth vesicles may have arisen by the uncoating of coated vesicles. Structures which eventually become labelled with cationized ferritin include multivesicular bodies, dictyosomes, large smooth vesicles, and a system of partially coated reticula.

Membrane-bound and fluid-phase macromolecules enter separate prelysosomal compartments in absorptive cells of suckling rat ileum

The absorptive cell of the suckling rat ileum is specialized for the uptake and digestion of milk macromolecules from the intestinal lumen. The apical cytoplasm contains an extensive tubulocisternal system, a variety of vesicles and multivesicular bodies (MVB), and a giant phagolysosomal vacuole where digestion is completed. To determine if sorting of membrane-bound and fluid-phase macromolecules occurs in this elaborate endocytic system, we infused adsorptive and soluble tracers into ligated intestinal loops in vivo and examined their fates. Lysosomal compartments were identified by acid phosphatase histochemistry. Native ferritin and two ferritin-lectin conjugates that do not bind to ileal membranes (Con A, UEAI) served as soluble tracers. Horseradish peroxidase binds to ileal membranes and thus was not useful as a fluid-phase tracer in this system. Cationized ferritin and a lectin that binds to terminal B-D-galactosyl sites on ileal membranes (Ricinus communis agglutinin [RCAI]-ferritin) were used as tracer ligands. All tracers entered the wide apical invaginations of the luminal cell surface and were transported intracellularly. Membrane-bound tracers were found in coated pits and vesicles, and throughout the tubulocisternal system (where cationized ferritin is released from the membrane) and later, in large clear vesicles and MVB. In contrast, fluid-phase tracers appeared within 5 min in vesicles of various sizes and were not transported through the tubulocisternae, rather, they were concentrated in a separate population of vesicles of increasing size that contained amorphous dense material. Large clear vesicles, large dense vesicles, and MVB eventually fused with the giant supranuclear vacuole. Acid phosphatase activity was present in MVB and in the giant vacuole but was not present in most large vesicles or in the tubulocisternae. These results demonstrate that membrane-bound and soluble protein are transported to a common lysosomal destination via separate intracellular routes involving several distinct prelysosomal compartments.

Class 1 major histocompatibility complex antigens on human extra-villous trophoblast

Using immunohistological techniques, class 1 products of the major histocompatibility complex (MHC) have been demonstrated on various forms of human extra-villous trophoblast in placental tissues taken from first, second and third trimester pregnancies. This contrasts with the absence of class 1 MHC antigens on all forms of villous trophoblast. The extra-villous trophoblast which reacted with antibodies to monomorphic class 1 MHC antigens consistently failed to bind HLA-A or HLA-B antibodies specific for the foetal phenotype. This suggests, but does not prove, that the MHC antigen expression of trophoblast may be restricted to HLA-C or some other undefined class 1 antigen.

Morphology, kinetics and secretory activity of antibody-forming cells

Specific antibody-forming cells from spleen, bone marrow and popliteal lymph nodes were studied in mice after subcutaneous priming and intravenous boosting with horseradish peroxidase (HRP). Functional antibody-secreting capacity of these cells was correlated with their morphology at the cell population level. For this purpose, cells synthesizing anti-HRP antibody from the same cell suspensions were studied simultaneously by light and electron microscopy and by a plaque assay. It appeared that the population of cells responsible for antibody synthesis as well as antibody secretion was morphologically heterogeneous: besides plasma cells, considerable numbers of antibody-forming lymphocytes, antibody-forming plasmablasts and antibody-forming immature plasma cells were observed. Immature plasma cells constituted the majority of antibody-forming as well as antibody-secreting cells. Among the immature plasma cells in the popliteal lymph nodes proliferation occurred. Evidence is presented that the light-microscopically identified mature plasma cell is not the main antibody-forming cell. It does not show 3H-Thymidine incorporation and should be considered as a non-dividing end-cell.

Emergence of a surface immunoglobulin recycling process during B lymphocyte differentiation

Surface immunoglobulin (Ig)-mediated endocytosis has been investigated in rat B lymphocytes and plasma cells, using horseradish peroxidase (HRP)-labeled sheep anti-rat Ig Fab' fragment of antibody and HRP as monomeric ligands, respectively. Quantitative estimates of HRP activity associated either with plasma membrane or with endomembrane compartments were made in several experimental conditions. Binding of HRP-conjugate on B lymphocytes was followed by its endocytosis in combination with surface Ig, as shown by the progressive disappearance of plasma membrane-associated HRP activity. Between 1 and 6 h at 37 degrees C in presence of conjugate the total amount of cell-associated activity was constant. These results indicate that during this time no reappearance of surface Ig occurred by neosynthesis, by the expression of an intracellular pool or by the recycling in a free form of the previously internalized molecules. On the contrary, at saturating doses, internalization of HRP by anti-HRP plasma cells increased linearly with time at 37 degrees C in presence of antigen, when, during the same time, the plasma membrane HRP-binding capacity remained constant. Cycloheximide did not affect continuous HRP uptake. The existence of a large intracellular pool of receptors has been ruled out by experiments of removal of binding sites with pronase. In addition, monensin caused a progressive decrease in the number of surface receptors on plasma cells but not on B lymphocytes. Our data then indicate that, unlike B lymphocytes, plasma cells were able to recycle their surface Ig.

Endocytosis and exocytosis: current concepts of vesicle traffic in animal cells

Animal cells have specific pathways to transport macromolecules from their surrounding environment to their interior, and from internal compartments to the cell surface or other intracellular locations. Many of these movements appear to be receptor-dependent processes in which specific membrane receptors bind macromolecules, segregate them into discrete membrane-limited compartments, and move the molecules to new locations. Such processes include the clustering and internalization of receptor-bound ligands at the cell surface in clathrin-coated pits, the formation of endocytic vesicles (receptosomes) from coated pits, the movement of receptosomes by saltatory motion to the Golgi system, the concentration of materials in the coated pits of the Golgi system that are destined for delivery to lysosomes, and the directed traffic of materials destined for exocytosis out of the Golgi to the cell surface. This review describes some of the experiments which have led to our current understanding of the various organelles involved in this traffic and some of the biochemical mechanisms involved.